openbios/fcode-utils/toke/flowcontrol.c
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Hash : d89219a0
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Date : 2017-06-08T18:57:07
Update contact information Remove obsolete email addresses and add OpenBIOS mailing list information. Signed-off-by: Stefan Reinauer <stefan.reinauer@coreboot.org>
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toke/flowcontrol.c
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/* * OpenBIOS - free your system! * ( FCode tokenizer ) * * This program is part of a free implementation of the IEEE 1275-1994 * Standard for Boot (Initialization Configuration) Firmware. * * Copyright (C) 2001-2010 Stefan Reinauer * * This program 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; version 2 of the License. * * This program 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 this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA, 02110-1301 USA * */ /* ************************************************************************** * * Support Functions for tokenizing FORTH Flow-Control structures. * * (C) Copyright 2005 IBM Corporation. All Rights Reserved. * Module Author: David L. Paktor dlpaktor@us.ibm.com * **************************************************************************** */ /* ************************************************************************** * * Functions Exported: * These first two do their work after the calling routine * has written the token for the required variant: * * mark_do Mark branches for "do" variants * resolve_loop Resolve "loop" variants' branches * * The remaining routines' descriptions are all similar: * Write the token(s), handle the outputs, mark * or resolve the branches, and verify correct * control-structure matching, for tokenizing * the ........................ statement in FORTH * emit_if IF * emit_else ELSE * emit_then THEN * emit_begin BEGIN * emit_again AGAIN * emit_until UNTIL * emit_while WHILE * emit_repeat REPEAT * emit_case CASE * emit_of OF * emit_endof ENDOF * emit_endcase ENDCASE * * Three additional routines deal with matters of overall balance * of the Control-Structures, and identify the start of any that * were not balanced. The first just displays Messages: * * announce_control_structs * * The other two clear and re-balance them: * * clear_control_structs_to_limit * clear_control_structs * **************************************************************************** */ /* ************************************************************************** * * Still to be done: * Correct analysis of Return-Stack usage around Flow-Control * constructs, including within Do-Loops or before Loop * Elements like I and J or UNLOOP or LEAVE. * Similarly, Return-Stack usage around IF ... ELSE ... THEN * statements needs analysis. For instance, the following: * * blablabla >R yadayada IF R> gubble ELSE flubble R> THEN * * is, in fact, correct, while something like: * * blablabla >R yadayada IF R> gubble THEN * * is an error. * * Implementing an analysis that would be sufficiently accurate * to justify reporting an ERROR with certainty (rather than * a mere WARNING speculatively) would probably require full * coordination with management of Flow-Control constructs, * and so is noted here. * **************************************************************************** */ #include <stdlib.h> #include <stdio.h> #include <string.h> #include "types.h" #include "toke.h" #include "emit.h" #include "vocabfuncts.h" #include "scanner.h" #include "stack.h" #include "errhandler.h" #include "flowcontrol.h" #include "stream.h" /* ************************************************************************** * * Global Variables Imported * opc FCode Output Buffer Position Counter * noerrors "Ignore Errors" flag, set by "-i" switch * do_loop_depth How deep we are inside DO ... LOOP variants * incolon State of tokenization; TRUE if inside COLON * statbuf The word just read from the input stream * iname Name of input file currently being processed * lineno Current line-number being processed * **************************************************************************** */ /* ************************************************************************** * * Global Variables Exported * control_stack_depth Number of items on "Control-Stack" * **************************************************************************** */ int control_stack_depth = 0; /* ************************************************************************** * * Internal Static Functions: * push_cstag Push an item onto the Control-Stack * pop_cstag Pop one item from the Control-Stack * control_stack_size_test Test C-S depth; report if error * control_structure_mismatch Print error-message * offset_too_large Print error-message * matchup_control_structure Error-check Control-Stack * matchup_two_control_structures Error-check two Control-Stack entries * emit_fc_offset Error-check and output FCode-Offset * control_structure_swap Swap control-struct branch-markers * mark_backward_target Mark target of backward-branch * resolve_backward Resolve backward-target for branch * mark_forward_branch Mark forward-branch * resolve_forward Resolve forward-branch at target * **************************************************************************** */ /* ************************************************************************** * * Internal Named Constants * Note: These control-structure identifier tags -- a.k.a. cstags -- * are used to identify the matching components of particular * control-structures. They are passed as parameters, and either * "Pushed" onto the "Control-Stack", or compared with what is on * "Top" of the "Control-Stack", as an error-check. * * name used by forth words: * BEGIN_CSTAG BEGIN AGAIN UNTIL REPEAT * IF_CSTAG IF ELSE THEN * WHILE_CSTAG WHILE REPEAT THEN * DO_CSTAG DO ?DO LOOP +LOOP * CASE_CSTAG CASE OF ENDCASE * OF_CSTAG OF ENDOF * ENDOF_CSTAG ENDOF ENDCASE * * The numbers assigned are arbitrary; they were selected for a * high unlikelihood of being encountered in normal usage, * and constructed with a hint of mnemonic value in mind. * **************************************************************************** */ /* Mnemonic: */ #define BEGIN_CSTAG 0xC57be916 /* CST BEGIN */ #define IF_CSTAG 0xC57A901f /* CSTAG (0) IF */ #define WHILE_CSTAG 0xC573412e /* CST WHILE */ #define DO_CSTAG 0xC57A90d0 /* CSTAG (0) DO */ #define CASE_CSTAG 0xC57Aca5e /* CSTA CASE */ #define OF_CSTAG 0xC57A90f0 /* CSTAG OF (0) */ #define ENDOF_CSTAG 0xC57e6d0f /* CST ENDOF */ /* ************************************************************************** * * Control-Structure identification, matching, completion and error * messaging will be supported by a data structure, which we * will call a CSTAG-Group * * It consists of one "Data-item" and several "Marker" items, thus: * * The Data-item in most cases will be a value of OPC (the Output * Buffer Position Counter) which will be used in calculating * an offset or placing an offset or both, as the case may be, * for the control structure in question. The one exception * is for a CSTAG-Group generated by a CASE statement; its * Data-item will be an integer count of the number of "OF"s * to be resolved when the ENDCASE statement is reached. * * The CSTAG for the FORTH word, as described above * The name of the input file in which the word was encountered * (actually, a pointer to a mem-alloc'ed copy of the filename) * The line number, within the input file, of the word's invocation * The Absolute Token Number in all Source Input of the word * The FORTH word that started the structure, (used in error messages) * A flag to indicate when two CSTAG-Groups are created together, * which will be used to prevent duplicate error messages when, * for instance, a DO is mismatched with a REPEAT . * **************************************************************************** */ /* ************************************************************************** * * "Control-Stack" Diagram Notation * * The CSTAG-Groups will be kept in an order resembling a data-stack, * (even though it won't be the data-stack itself). We will refer * to this list of structures as the "Control Stack", and in our * comments we will show their arrangement in a format resembling * stack-diagram remarks. * * In these "Control-Stack Diagrams", we will use the notation: * <Stmt>_{FOR|BACK}w_<TAGNAM> * to represent a CSTAG-Group generated by a <Stmt> -type of * statement, with a "FORw"ard or "BACKw"ard branch-marker and * a CSTAG of the <TAGNAM> type. * * A CASE-CSTAG-Group will have a different notation: * N_OFs...CASE_CSTAG * * In all cases, a CSTAG-Group will be manipulated as a unit. * * The notation for Control-Stack Diagram remarks will largely resemble * the classic form used in FORTH, i.e., enclosed in parentheses, * lowest item to the left, top item on the right, with a double- * hyphen to indicate "before" or "after". * * Enclosure in {curly-braces} followed by a subscript-range indicates * that the Stack-item or Group is repeated. * **************************************************************************** */ /* ************************************************************************** * * We are not keeping the "Control Stack" structures on the regular * data stack because a sneaky combination of user-inputs could * throw things into chaos were we to use that scheme. Consider * what would happen if a number were put on the stack, say, in * tokenizer-escape mode, in between elements of a flow-control * structure... Theoretically, there is no reason to prohibit * that, but it would be unexpectedly problematical for most * FORTH-based tokenizers. * * Maintaining the "Control Stack" structures in a linked-list would * be a more nearly bullet-proof approach. The theory of operation * would be the same, broadly speaking, and there would be no need * to check for NOT_CSTAG and no risk of getting the elements of * the control-structures out of sync. * **************************************************************************** */ /* ************************************************************************** * * Structure Name: cstag_group_t * Synopsis: Control-Structure Tag Group * * Fields: * cs_tag Control-structure identifier tag * cs_inp_fil Name of input file where C-S was started * cs_line_num Line-number in Current Source when C-S was started * cs_abs_token_num "Absolute" Token Number when C-S was started * cs_word The FORTH word that started the C-S * cs_not_dup FALSE if second "Control Stack" entry for same word * cs_datum Data-Item of the Group * prev Pointer to previous CSTAG-Group in linked-list * * All data using this structure will remain private to this file, * so we declare it here rather than in the .h file * **************************************************************************** */ typedef struct cstag_group { unsigned long cs_tag; char *cs_inp_fil; unsigned int cs_line_num; unsigned int cs_abs_token_num; char *cs_word; bool cs_not_dup; unsigned long cs_datum; struct cstag_group *prev; } cstag_group_t; /* ************************************************************************** * * Internal Static Variables * control_stack "Thread" Pointer to the linked-list of * "Control Stack" structure entries * not_cs_underflow Flag used to prevent duplicate messages * not_consuming_two Flag used to prevent loss of messages * didnt_print_otl Flag used to prevent duplicate messages * **************************************************************************** */ static cstag_group_t *control_stack = NULL; /* "Top" of the "Stack" */ /* ************************************************************************** * * not_cs_underflow is used only by routines that make two calls to * resolve a marker. It is set TRUE before the first call; if * that call had a control-stack underflow, the error-message * routine resets it to FALSE. The calling routine can then * test it as the condition for the second call. * Routines that make only one call to resolve a marker can ignore it. * **************************************************************************** */ static bool not_cs_underflow; /* No need to initialize. */ /* ************************************************************************** * * not_consuming_two is also used only by routines that make two calls * to resolve a marker, but for this case, those routines only need * to reset it to FALSE and not to test it; that will be done by * the control_structure_mismatch() routine when it looks at * the cs_not_dup field. If the mismatch occurred because of * a combination of control-structures that consume one each, * the message will be printed even for the second "Control Stack" * entry. The routine that changed it will have to set it back to * TRUE when it's done with it. * * didnt_print_otl is used similarly, but only for the offset-too-large * error in the DO ... LOOP type of control-structures. * **************************************************************************** */ static bool not_consuming_two = TRUE; static bool didnt_print_otl = TRUE; /* ************************************************************************** * * Function name: push_cstag * Synopsis: Push a new CSTAG-Group onto the front ("Top") * of the (notional) Control-Stack. * * Inputs: * Parameters: * cstag ID Tag for Control-Structure to "Push" * datum The Data-Item for the new CSTAG-Group * Global Variables: * iname Name of input file currently being processed * lineno Current-Source line-number being processed * abs_tokenno "Absolute"Token Number of word being processed * statbuf The word just read, which started the C-S * Local Static Variables: * control_stack Will become the new entry's "prev" * * Outputs: * Returned Value: None * Global Variables: * control_stack_depth Incremented * Local Static Variables: * control_stack Will become the "previous" entry in the list * Items Pushed onto Control-Stack: * Top: A new CSTAG-Group, params as given * Memory Allocated * New CSTAG-Group structure * Duplicate of name of current input file * Duplicate of word just read * When Freed? * When Removing a CSTAG-Group, in pop_cstag() * **************************************************************************** */ static void push_cstag( unsigned long cstag, unsigned long datum) { cstag_group_t *cs_temp; cs_temp = control_stack; control_stack = safe_malloc( sizeof(cstag_group_t), "pushing CSTag"); control_stack->cs_tag = cstag; control_stack->cs_inp_fil = strdup(iname); control_stack->cs_line_num = lineno; control_stack->cs_abs_token_num = abs_token_no; control_stack->cs_word = strdup(statbuf); control_stack->cs_not_dup = TRUE; control_stack->cs_datum = datum; control_stack->prev = cs_temp; control_stack_depth++; } /* ************************************************************************** * * Function name: pop_cstag * Synopsis: Remove a CSTAG-Group from the front ("Top") of the * (notional) Control-Stack. * * Inputs: * Parameters: NONE * Global Variables: * Local Static Variables: * control_stack CSTAG-Group on "Top" * * Outputs: * Returned Value: NONE * Global Variables: * control_stack_depth Decremented * Local Static Variables: * control_stack "Previous" entry will become current * Memory Freed * mem-alloc'ed copy of input filename * mem-alloc'ed copy of Control-structure FORTH word * CSTAG-Group structure * Control-Stack, # of Items Popped: 1 * * Process Explanation: * The calling routine might not check for empty Control-Stack, * so we have to be sure and check it here. * **************************************************************************** */ static void pop_cstag( void) { if ( control_stack != NULL ) { cstag_group_t *cs_temp; cs_temp = control_stack->prev; free( control_stack->cs_word ); free( control_stack->cs_inp_fil ); free( control_stack ); control_stack = cs_temp; control_stack_depth--; } } /* ************************************************************************** * * Function name: control_stack_size_test * Synopsis: Detect Control Stack underflow; report if an ERROR. * * Inputs: * Parameters: * min_depth Minimum depth needed * Global Variables: * control_stack_depth Current depth of Control Stack * statbuf Word to name in error message * * Outputs: * Returned Value: TRUE if adequate depth * Local Static Variables: * not_cs_underflow Reset to FALSE if underflow detected. * Printout: * Error message is printed. * Identify the colon definition if inside one. * * Process Explanation: * Some statements need more than one item on the Control Stack; * they will do their own control_stack_depth testing and * make a separate call to this routine. * **************************************************************************** */ static bool control_stack_size_test( int min_depth ) { bool retval = TRUE; if ( control_stack_depth < min_depth ) { retval = FALSE; tokenization_error ( TKERROR, "Control-Stack underflow at %s", strupr(statbuf) ); in_last_colon( TRUE); not_cs_underflow = FALSE; /* See expl'n early on in this file */ } return( retval ); } /* ************************************************************************** * * Function name: control_structure_mismatch * Synopsis: Report an ERROR after a Control Structure mismatch * was detected. * * Inputs: * Parameters: NONE * Global Variables: * statbuf Word encountered, to name in error message * Local Static Variables: * control_stack "Pushed" Control-Structure Tag Group * not_consuming_two See explanation early on in this file * Control-Stack Items: * Top: "Current" Control-Structure Tag Group * Some of its "Marker" information * will be used in the error message * * Outputs: * Returned Value: NONE * Printout: * Error message is printed * * Process Explanation: * This routine is called after a mismatch is detected, and * before the CSTAG-Group is "Popped" from the notional * Control-Stack. * If the control_stack pointer is NULL, print a different * Error message * Don't print if the "Control Stack" entry is a duplicate and * we're processing a statement that consumes two entries. * **************************************************************************** */ static void control_structure_mismatch( void ) { if ( control_stack->cs_not_dup || not_consuming_two ) { tokenization_error ( TKERROR, "The %s is mismatched with the %s" , strupr(statbuf), strupr(control_stack->cs_word)); where_started( control_stack->cs_inp_fil, control_stack->cs_line_num ); } } /* ************************************************************************** * * Function name: offset_too_large * Synopsis: Report an ERROR after a too-large fcode-offset * was detected. * * Inputs: * Parameters: * too_large_for_16 TRUE if the offset is too large to be * expressed as a 16-bit signed number. * Global Variables: * statbuf Word encountered, to name in error message * offs16 Whether we are using 16-bit offsets * Local Static Variables: * control_stack "Pushed" Control-Structure Tag Group * didnt_print_otl Switch to prevent duplicate message * Control-Stack Items: * Top: "Current" Control-Structure Tag Group * Some of its "Marker" information * will be used in the error message * * Outputs: * Returned Value: NONE * Local Static Variables: * didnt_print_otl Will be reset to FALSE * * Printout: * Error message: * Branch offset too large between <here> and <there> * Advisory message, if we are using 8-bit offsets, will * indicate whether switching to 16-bit offsets would help * * Process Explanation: * Two branches are involved in a DO ... LOOP structure: an "outer" * forward-branch and a slightly smaller "inner" backward-branch. * In the majority of cases, if one offset exceeds the limit, * both will. There is, however, a very small but distinct * possibility that the offset for the smaller branch will not * exceed the limit while the larger one does. To prevent two * messages from being printed in the routine instance, but still * assure that one will be printed in the rare eventuality, we * utilize the flag called didnt_print_otl in conjunction * with the cs_not_dup field. * **************************************************************************** */ static void offset_too_large( bool too_large_for_16 ) { if ( control_stack->cs_not_dup || didnt_print_otl ) { tokenization_error( TKERROR, "Branch offset is too large between %s and the %s" , strupr(statbuf), strupr(control_stack->cs_word)); where_started( control_stack->cs_inp_fil, control_stack->cs_line_num ); if ( INVERSE( offs16 ) ) { if ( too_large_for_16 ) { tokenization_error ( INFO, "Offset would be too large even if 16-bit offsets " "were in effect.\n"); }else{ tokenization_error ( INFO, "Offset might fit if 16-bit offsets " "(e.g., fcode-version2) were used.\n" ); } } } didnt_print_otl = FALSE; } /* ************************************************************************** * * Function name: emit_fc_offset * Synopsis: Test whether the given FCode-Offset is out-of-range; * before placing it into the FCode Output Buffer. * * Inputs: * Parameters: * fc_offset The given FCode-Offset * Global Variables: * offs16 Whether we are using 16-bit offsets * noerrors "Ignore Errors" flag * * Outputs: * Returned Value: NONE * * Error Detection: * Error if the given FCode-Offset exceeds the range that can * be expressed by the size (i.e., 8- or 16- -bits) of the * offsets we are using. Call offset_too_large() to print * the Error message; also, if noerrors is in effect, issue * a Warning showing the actual offset and how it will be coded. * * Process Explanation: * For forward-branches, the OPC will have to be adjusted to * indicate the location that was reserved for the offset * to be written, rather than the current location. That * will all be handled by the calling routine. * We will rely on "C"'s type-conversion (type-casting) facilities. * Look at the offset value both as an 8-bit and as a 16-bit offset, * then determine the relevant course of action. * **************************************************************************** */ static void emit_fc_offset( int fc_offset) { int fc_offs_s16 = (s16)fc_offset; int fc_offs_s8 = (s8)fc_offset; bool too_large_for_8 = BOOLVAL( fc_offset != fc_offs_s8 ); bool too_large_for_16 = BOOLVAL( fc_offset != fc_offs_s16); if ( too_large_for_16 || ( INVERSE(offs16) && too_large_for_8 ) ) { offset_too_large( too_large_for_16 ); if ( noerrors ) { int coded_as = offs16 ? (int)fc_offs_s16 : (int)fc_offs_s8 ; tokenization_error( WARNING, "Actual offset is 0x%x (=dec %d), " "but it will be coded as 0x%x (=dec %d).\n", fc_offset, fc_offset, coded_as, coded_as ); } } emit_offset( fc_offs_s16 ); } /* ************************************************************************** * * Function name: matchup_control_structure * Synopsis: Error-check. Compare the given control-structure * identifier tag with the one in the CSTAG-Group * on "Top" of the "Control Stack". * If they don't match, report an error, and, if not * "Ignoring Errors", return Error indication. * If no error, pass the Data-item back to the caller. * Do not consume the CSTAG-Group; that will be the * responsibility of the calling routine. * * Inputs: * Parameters: * cstag Control-struc ID Tag expected by calling function * Global Variables: * noerrors "Ignore Errors" flag * Local Static Variables: * control_stack "Pushed" (current) Control-Structure Tag Group * Control-Stack Items: * Top: Current CSTAG-Group * * Outputs: * Returned Value: TRUE = Successful match, no error. * * Error Detection: * Control Stack underflow or cstag mismatch. See below for details. * * Process Explanation: * If the expected cstag does not match the cs_tag from the CSTAG * Group on "Top" of the "Control Stack", print an ERROR message, * and, unless the "Ignore Errors" flag is in effect, prepare * to return FALSE. * However, if we've "underflowed" the "Control Stack", we dare not * ignore errors; that could lead to things like attempting to * write a forward-branch FCode-offset to offset ZERO, over the * FCODE- or PCI- -header block. We don't want that... * So, if the control_stack pointer is NULL, we will print an * ERROR message and immediately return FALSE. * Since we will not consume the CSTAG-Group, the calling routine * can access the Data-Item and any "Marker" information it may * still require via the local control_stack pointer. The caller * will be responsible for removing the CSTAG-Group. * * Special Exception to "Ignore Errors": * At the last usage of the CASE_CSTAG , for the ENDCASE statement, * this routine will be called to control freeing-up memory, etc. * For the OF statement, it will be called to control incrementing * the OF-count datum. * Processing an ENDCASE statement with the datum from any other * CSTAG-Group can lead to a huge loop. * Processing any other "resolver" with the datum from an ENDCASE * CSTAG-Group can lead to mistaking a very low number for an * offset into the Output Buffer and attempting to write to it. * Incrementing the datum from any other CSTAG-Group can lead to * a variety of unacceptable errors, too many to guess. * So, if either the given cstag or the cs_tag field of the "Top" * CSTAG-Group is a CASE_CSTAG , we will not ignore errors. * **************************************************************************** */ static bool matchup_control_structure( unsigned long cstag ) { bool retval = FALSE; if ( control_stack_size_test( 1) ) { retval = TRUE; if ( control_stack->cs_tag != cstag ) { control_structure_mismatch(); if ( ( INVERSE(noerrors) ) || ( cstag == CASE_CSTAG ) || ( control_stack->cs_tag == CASE_CSTAG ) ) { retval = FALSE; } } } return ( retval ); } /* ************************************************************************** * * Function name: control_structure_swap * Synopsis: Swap control-structure branch-marker Groups * * Inputs: * Parameters: NONE * Local Static Variables: * control_stack Pointer to "Control Stack" linked-list * Control-Stack Items: * Top: CSTAG-Group_0 * Next: CSTAG-Group_1 * * Outputs: * Returned Value: NONE * Local Static Variables: * control_stack Points to former "previous" and vice-versa * Items on Control-Stack: * Top: CSTAG-Group_1 * Next: CSTAG-Group_0 * * Error Detection: * If control-stack depth is not at least 2, CS underflow ERROR. * This might trigger other routines' error detections also... * * Extraneous Remarks: * Before control-structure identification was implemented, offsets * were kept on the data-stack, and this was a single SWAP. * When CSTAGs were added, the "Group" was only a pair kept on the * data-stack -- the CSTAG and the Data-item -- and this * became a TWO_SWAP() * For a while, when I tried keeping the CSTAG-Group on the stack, * this became a FOUR_SWAP() * That turned out to be unacceptably brittle; this way is much * more robust. * I am so glad I called this functionality out into a separate * routine, early on in the development process. * * This is the function called 1 CSROLL in section A.3.2.3.2 * of the ANSI Forth spec, which likewise corresponds to the * modifier that Wil Baden, in his characteristically elegant * nomenclature, dubbed: BUT * **************************************************************************** */ static void control_structure_swap( void ) { if ( control_stack_size_test( 2) ) { cstag_group_t *cs_temp; cs_temp = control_stack->prev; control_stack->prev = cs_temp->prev; cs_temp->prev = control_stack; control_stack = cs_temp; } } /* ************************************************************************** * * Function name: matchup_two_control_structures * Synopsis: For functions that resolve two CSTAG-Groups, both * matchup both "Top of Control Stack" entries * before processing them... * * Inputs: * Parameters: * top_cstag Control-struc ID Tag expected on "Top" CS entry * next_cstag Control-struc ID Tag expected on "Next" CS entry * Local Static Variables: * not_cs_underflow Used for underflow detection. * Control-Stack Items: * Top: Current CSTAG-Group * Next: Next CSTAG-Group * * Outputs: * Returned Value: TRUE = Successful matches, no error. * Global Variables: * noerrors "Ignore Errors" flag; cleared, then restored * Local Static Variables: * not_consuming_two Cleared, then restored * Control-Stack, # of Items Popped: 2 (if matches unsuccessful) * * Error Detection: * Control Stack underflow detected by control_structure_swap() * Control Structure mismatch detected by control_structure_mismatch() * * Process Explanation: * We will use matchup_control_structure() to do the "heavy lifting". * We will not be ignoring errors in these cases. * Save the results of a match of top_cstag * Swap the top two CS entries. * If an underflow was detected, there's no more matching to be done. * Otherwise: * Save the results of a match of next_cstag * Swap the top two CS entries again, to their original order. * The result is TRUE if both matches were successful. * If the matches were not successful, consume the top two entries * (unless there's only one, in which case consume it). * **************************************************************************** */ static bool matchup_two_control_structures( unsigned long top_cstag, unsigned long next_cstag) { bool retval; bool topmatch; bool nextmatch = FALSE; bool sav_noerrors = noerrors; noerrors = FALSE; not_consuming_two = FALSE; not_cs_underflow = TRUE; topmatch = matchup_control_structure( top_cstag); if ( not_cs_underflow ) { control_structure_swap(); if ( not_cs_underflow ) { nextmatch = matchup_control_structure( next_cstag); control_structure_swap(); } } retval = BOOLVAL( topmatch && nextmatch); if ( INVERSE( retval) ) { pop_cstag(); pop_cstag(); } not_consuming_two = TRUE; noerrors = sav_noerrors; return ( retval ); } /* ************************************************************************** * * Function name: mark_backward_target * Synopsis: Mark the target of an expected backward-branch * * Associated FORTH words: BEGIN DO ?DO * * Inputs: * Parameters: * cstag Control-structure ID tag for calling function * Global Variables: * opc Output Buffer Position Counter * * Outputs: * Returned Value: NONE * Items Pushed onto Control-Stack: * Top: <Stmt>_BACKw_<TAGNAM> * * Process Explanation: * Just before this function is called, the token that begins the * control-structure was written to the FCode Output buffer. * OPC, the FCode Output Buffer Position Counter, is at the * destination to which the backward-branch will be targeted. * Create a CSTAG-Group with the given C-S Tag, and OPC as its datum; * push it onto the Control-Stack. * Later, when the backward-branch is installed, the FCode-offset * will be calculated as the difference between the OPC at * that time and the target-OPC we saved here. * **************************************************************************** */ static void mark_backward_target(unsigned long cstag ) { push_cstag( cstag, (unsigned long)opc); } /* ************************************************************************** * * Function name: mark_forward_branch * Synopsis: Mark the location of, and reserve space for, the * FCode-offset associated with a forward branch. * * Associated FORTH words: IF WHILE ELSE * * Inputs: * Parameters: * cstag Control-structure ID tag for calling function * * Outputs: * Returned Value: NONE * Items Pushed onto Control-Stack: * Top: <Stmt>_FORw_<TAGNAM> * FCode Output buffer: * Place-holder FCode-offset of zero. * * Process Explanation: * Just before this function is called, the forward-branch token * that begins the control-structure was written to the FCode * Output buffer. * It will need an FCode-offset to the destination to which it will * be targeted, once that destination is known. * Create a CSTAG-Group with the given C-S Tag, and OPC as its datum; * push it onto the Control-Stack. (This is the same action as * for marking a backward-target.) * Then write a place-holder FCode-offset of zero to the FCode * Output buffer. * Later, when the destination is known, the FCode-offset will be * calculated as the difference between the OPC at that time * and the FCode-offset location we're saving now. That offset * will be over-written onto the place-holder offset of zero at * the location in the Output buffer that we saved on the * Control-Stack in this routine. * **************************************************************************** */ static void mark_forward_branch(unsigned long cstag ) { mark_backward_target(cstag ); emit_offset(0); } /* ************************************************************************** * * Function name: resolve_backward * Synopsis: Resolve backward-target when a backward branch * is reached. Write FCode-offset to reach saved * target from current location. * * Associated FORTH words: AGAIN UNTIL REPEAT * LOOP +LOOP * * Inputs: * Parameters: * cstag Control-structure ID tag for calling function * Global Variables: * opc Output Buffer Position Counter * Control-Stack Items: * Top: <Stmt>_BACKw_<TAGNAM> * * Outputs: * Returned Value: NONE * Global Variables: * opc Incremented by size of an FCode-offset * Control-Stack, # of Items Popped: 1 * FCode Output buffer: * FCode-offset to reach backward-target * * Error Detection: * Test for Control-structure ID tag match. * * Process Explanation: * Just before this function is called, the backward-branch token * that ends the control-structure was written to the FCode * Output buffer. * The current OPC is at the point from which the FCode-offset * is to be calculated, and at which it is to be written. * The top of the Control-Stack should have the CSTAG-Group from * the statement that prepared the backward-branch target that * we expect to resolve. Its datum is the OPC of the target * of the backward branch. * If the supplied Control-structure ID tag does not match the one * on top of the Control-Stack, announce an error. We will * still write an FCode-offset, but it will be a place-holder * of zero. * Otherwise, the FCode-offset we will write will be the difference * between the target-OPC and our current OPC. * **************************************************************************** */ static void resolve_backward( unsigned long cstag) { unsigned long targ_opc; int fc_offset = 0; if ( matchup_control_structure( cstag) ) { targ_opc = control_stack->cs_datum; fc_offset = targ_opc - opc; } emit_fc_offset( fc_offset ); pop_cstag(); } /* ************************************************************************** * * Function name: resolve_forward * Synopsis: Resolve a forward-branch when its target has been * reached. Write the FCode-offset into the space * that was reserved. * * Associated FORTH words: ELSE THEN REPEAT * LOOP +LOOP * * Inputs: * Parameters: * cstag Control-structure ID tag for calling function * Global Variables: * opc Output Buffer Position Counter * Control-Stack Items: * Top: <Stmt>_FORw_<TAGNAM> * * Outputs: * Returned Value: NONE * Global Variables: * opc Changed, then restored. * Control-Stack, # of Items Popped: 1 * FCode Output buffer: * FCode-offset is written to location where space was reserved * when the forward-branch was marked. * * Error Detection: * Test for Control-structure ID tag match. * * Process Explanation: * Just before this function is called, the last token -- and * possibly, FCode-offset -- that is within the scope of * what the branch might skip was written to the FCode * Output buffer. * The current OPC is at the point from which the FCode-offset * is to be calculated, but not at which it is to be written. * The top of the Control-Stack should have the CSTAG-Group from * the statement that prepared the forward-branch we expect * to resolve, and for which our current OPC is the target. * Its datum is the OPC of the space that was reserved for * the forward-branch whose target we have just reached. * If the supplied Control-structure ID tag does not match the one * on top of the Control-Stack, announce an error and we're done. * Otherwise, the datum is used both as part of the calculation of * the FCode-offset we are about to write, and as the location * to which we will write it. * The FCode-offset is calculated as the difference between our * current OPC and the reserved OPC location. * We will not be ignoring errors in these cases, because we would * be over-writing something that might not be a place-holder * for a forward-branch at an earlier location in the FCode * Output buffer. * **************************************************************************** */ static void resolve_forward( unsigned long cstag) { unsigned long resvd_opc; bool sav_noerrors = noerrors; bool cs_match_result; noerrors = FALSE; /* Restore the "ignore-errors" flag before we act on our match result * because we want it to remain in effect for emit_fc_offset() */ cs_match_result = matchup_control_structure( cstag); noerrors = sav_noerrors; if ( cs_match_result ) { int saved_opc; int fc_offset; resvd_opc = control_stack->cs_datum; fc_offset = opc - resvd_opc; saved_opc = opc; opc = resvd_opc; emit_fc_offset( fc_offset ); opc = saved_opc; } pop_cstag(); } /* ************************************************************************** * * The functions that follow are the exported routines that * utilize the preceding support-routines to effect their * associated FORTH words. * * The routines they call will take care of most of the Error * Detection via stack-depth checking and Control-structure * ID tag matching, so those will not be called-out in the * prologues. * **************************************************************************** */ /* ************************************************************************** * * Function name: emit_if * Synopsis: All the actions when IF is encountered * * Associated FORTH word: IF * * Inputs: * Parameters: NONE * * Outputs: * Returned Value: NONE * Items Pushed onto Control-Stack: * Top: If_FORw_IF * FCode Output buffer: * Token for conditional branch -- b?branch -- followed by * place-holder of zero for FCode-offset * * **************************************************************************** */ void emit_if( void ) { emit_token("b?branch"); mark_forward_branch( IF_CSTAG ); } /* ************************************************************************** * * Function name: emit_then * Synopsis: All the actions when THEN is encountered; also * part of another forward-branch resolver's action. * * Associated FORTH words: THEN ELSE * * Inputs: * Parameters: NONE * Local Static Variables: * control_stack Points to "Top" Control-Structure Tag Group * Control-Stack Items: * Top: If_FORw_IF | While_FORw_WHILE * * Outputs: * Returned Value: NONE * Control-Stack, # of Items Popped: 1 * FCode Output buffer: * Token for forward-resolve -- b(>resolve) -- then the space * reserved for the forward-branch FCode-offset is filled * in so that it reaches the token after the b(>resolve) . * * Process Explanation: * The THEN statement or the ELSE statement must be able to resolve * a WHILE statement, in order to implement the extended flow- * -control structures as described in sec. A.3.2.3.2 of the * ANSI Forth Spec. * But we must prevent the sequence IF ... BEGIN ... REPEAT from * compiling as though it were: IF ... BEGIN ... AGAIN THEN * We do this by having a separate CSTAG for WHILE and allowing * it here but not allowing the IF_CSTAG when processing REPEAT. * **************************************************************************** */ void emit_then( void ) { emit_token("b(>resolve)"); if ( control_stack != NULL ) { if ( control_stack->cs_tag == WHILE_CSTAG ) { control_stack->cs_tag = IF_CSTAG; } } resolve_forward( IF_CSTAG ); } /* ************************************************************************** * * Function name: emit_else * Synopsis: All the actions when ELSE is encountered * * Associated FORTH word: ELSE * * Inputs: * Parameters: NONE * Global Variables: * control_stack_depth Current depth of Control Stack * Local Static Variables: * not_cs_underflow If this is FALSE after the c-s swap, it * means an underflow resulted; skip * the call to resolve the first marker. * Control-Stack Items: * Top: {If_FORw_IF}1 * (Datum is OPC of earlier forward-branch; must be resolved.) * * Outputs: * Returned Value: NONE * Control-Stack, # of Items Popped: 1 * Items Pushed onto Control-Stack: * Top: {If_FORw_IF}2 * (Datum is current OPC, after forward-branch is placed.) * FCode Output buffer: * Token for unconditional branch -- bbranch-- followed by * place-holder of zero for FCode-offset. Then, token * for forward-resolve -- b(>resolve) -- and the space * reserved earlier for the conditional forward-branch * FCode-offset is filled in to reach the token after * the b(>resolve) . * * Error Detection: * If the "Control-Stack" is empty, bypass the forward branch * and let the call to control_structure_swap() report * the underflow error. Then use not_cs_underflow to * control whether to resolve the forward-branch. * * Process Explanation: * The final item needed within the scope of what the earlier * conditional branch might skip is an unconditional branch * over the "else"-clause to follow. After that, the earlier * conditional branch needs to be resolved. This last step * is identical to the action of THEN . * **************************************************************************** */ void emit_else( void ) { if ( control_stack_depth > 0 ) { emit_token("bbranch"); mark_forward_branch( IF_CSTAG ); } not_cs_underflow = TRUE; control_structure_swap(); if ( not_cs_underflow ) { emit_then(); } } /* ************************************************************************** * * Function name: emit_begin * Synopsis: All the actions when BEGIN is encountered * * Associated FORTH word: BEGIN * * Inputs: * Parameters: NONE * * Outputs: * Returned Value: NONE * Items Pushed onto Control-Stack: * Top: Begin_BACKw_BEGIN * (Datum is current OPC, target of future backward-branch) * FCode Output buffer: * Token for target of backward branch -- b(<mark) * **************************************************************************** */ void emit_begin( void ) { emit_token("b(<mark)"); mark_backward_target( BEGIN_CSTAG ); } /* ************************************************************************** * * Function name: emit_again * Synopsis: All the actions when AGAIN is encountered * * Associated FORTH words: AGAIN REPEAT * * Inputs: * Parameters: NONE * Control-Stack Items: * Top: Begin_BACKw_BEGIN * (Datum is OPC of backward-branch target at BEGIN) * * Outputs: * Returned Value: NONE * Control-Stack, # of Items Popped: 1 * FCode Output buffer: * Token for unconditional branch -- bbranch -- followed by * FCode-offset that reaches just after the b(<mark) * token at the corresponding BEGIN statement. * * Process Explanation: * The FCode-offset is calculated as the difference between our * current OPC and the target-OPC saved on the Control-Stack. * **************************************************************************** */ void emit_again( void ) { emit_token("bbranch"); resolve_backward( BEGIN_CSTAG ); } /* ************************************************************************** * * Function name: emit_until * Synopsis: All the actions when UNTIL is encountered * * Associated FORTH word: UNTIL * * Process Explanation: * Same as AGAIN except token is conditional branch -- b?branch -- * instead of unconditional. * **************************************************************************** */ void emit_until( void ) { emit_token("b?branch"); resolve_backward( BEGIN_CSTAG ); } /* ************************************************************************** * * Function name: emit_while * Synopsis: All the actions when WHILE is encountered * * Associated FORTH word: WHILE * * Inputs: * Parameters: NONE * Global Variables: * control_stack_depth Number of items on "Control-Stack" * Control-Stack Items: * Top: Begin_BACKw_BEGIN * (Datum is OPC of backward-branch target) * * Outputs: * Returned Value: NONE * Control-Stack: 1 item added below top item. * Items on Control-Stack: * Top: Begin_BACKw_BEGIN * Next: While_FORw_WHILE * FCode Output buffer: * Token for conditional branch -- b?branch -- followed by * place-holder of zero for FCode-offset * * Error Detection: * If the "Control-Stack" is empty, bypass creating the branch * and let the call to control_structure_swap() report * the underflow error. * * Process Explanation: * Output a conditional forward-branch sequence, similar to IF * (except with a WHILE CSTAG), but be sure to leave the * control-structure branch-marker that was created by the * preceding BEGIN on top of the one just generated: * the BEGIN needs to be resolved first in any case, and * doing this here is the key to implementing the extended * control-flow structures as described in sec. A.3.2.3.2 * of the ANSI Forth Spec. * * Extraneous Remarks: * It was for the use of this function that Wil Baden coined the * name BUT for the control-structure swap routine. The idea * was that the implementation of WHILE could be boiled down * to: IF BUT (couldn't quite fit an AND in there...;-} ) * Naturally, this implementation is a smidgeon more complicated... * **************************************************************************** */ void emit_while( void ) { if ( control_stack_depth > 0 ) { emit_token("b?branch"); mark_forward_branch( WHILE_CSTAG ); } control_structure_swap(); } /* ************************************************************************** * * Function name: emit_repeat * Synopsis: All the actions when REPEAT is encountered * * Associated FORTH word: REPEAT * * Inputs: * Parameters: NONE * Local Static Variables: * not_cs_underflow If FALSE after first call to resolve marker, * an underflow resulted; skip second call. * Control-Stack Items: * Top: Begin_BACKw_BEGIN * (Datum is OPC of backward-branch target at BEGIN) * Next: If_FORw_IF * (Datum is OPC of FCode-offset place-holder) * * Outputs: * Returned Value: NONE * Local Static Variables: * not_consuming_two Cleared, then restored * Control-Stack, # of Items Popped: 2 * FCode Output buffer: * Token for unconditional branch -- bbranch -- followed by * FCode-offset that reaches just after the b(<mark) * token at the corresponding BEGIN statement. Then * the token for forward-resolve -- b(>resolve) -- and * the space reserved for the conditional forward-branch * FCode-offset is filled in so that it reaches the token * after the b(>resolve) . * * Process Explanation: * The action is identical to that taken for AGAIN followed * by the action for THEN. * The Local Static Variable not_consuming_two gets cleared * and restored by this routine. * **************************************************************************** */ void emit_repeat( void ) { if ( matchup_two_control_structures( BEGIN_CSTAG, WHILE_CSTAG ) ) { not_cs_underflow = TRUE; not_consuming_two = FALSE; emit_again(); if ( not_cs_underflow ) { emit_token("b(>resolve)"); resolve_forward( WHILE_CSTAG ); } not_consuming_two = TRUE; } } /* ************************************************************************** * * Function name: mark_do * Synopsis: Common routine for marking the branches for * the "do" variants * * Associated FORTH words: DO ?DO * * Inputs: * Parameters: NONE * * Outputs: * Returned Value: NONE * Global Variables: * do_loop_depth Incremented * Items Pushed onto Control-Stack: * Top: Do_FORw_DO * Next: Do_BACKw_DO * FCode Output buffer: * Place-holder of zero for FCode-offset * * Error Detection: * The do_loop_depth counter will be used by other routines * to detect misplaced "LEAVE", "UNLOOP", "I" and suchlike. * (Imbalanced "LOOP" statements are detected by the CSTag * matching mechanism.) * * Process Explanation: * Just before this function is called, the forward-branching token * for the "DO" variant that begins the control-structure was * written to the FCode Output buffer. * It needs an FCode-offset for a forward-branch to just after * its corresponding "LOOP" variant and the FCode-offset * associated therewith. * That "LOOP" variant's associated FCode-offset is targeted * to the token that follows the one for this "DO" variant * and its FCode-offset. * Mark the forward-branch with the C-S Tag for DO and write a * place-holder FCode-offset of zero to FCode Output. * Indicate that the mark that will be processed second (but which * was made first) is a duplicate of the one that will be * processed first. * Then mark the backward-branch target, also with the DO C-S Tag. * Finally, increment the do_loop_depth counter. * * Extraneous Remarks: * This is more complicated to describe than to code... ;-) * **************************************************************************** */ void mark_do( void ) { mark_forward_branch( DO_CSTAG); control_stack->cs_not_dup = FALSE; mark_backward_target( DO_CSTAG); do_loop_depth++; } /* ************************************************************************** * * Function name: resolve_loop * Synopsis: Common routine for resolving the branches for * the "loop" variants. * * Associated FORTH words: LOOP +LOOP * * Inputs: * Parameters: NONE * Global Variables: * statbuf Word read from input stream (either "loop" * or "+loop"), used for Error Message. * Local Static Variables: * not_cs_underflow If FALSE after first call to resolve marker, * an underflow resulted; skip second call. * Control-Stack Items: * Top: Do_FORw_DO * Next: Do_BACKw_DO * * Outputs: * Returned Value: NONE * Global Variables: * do_loop_depth Decremented * Local Static Variables: * not_consuming_two Cleared, then restored * didnt_print_otl Set, then set again at end. * Control-Stack, # of Items Popped: 2 * FCode Output buffer: * FCode-offset that reaches just after the token of the * corresponding "DO" variant. Then the space reserved * for the FCode-offset of the forward-branch associated * with the "DO" variant is filled in so that it reaches * the token just after the "DO" variant's FCode-offset. * * Error Detection: * A value of zero in do_loop_depth before it's decremented * indicates a DO ... LOOP imbalance, which is an ERROR, * but our other error-reporting mechanisms will catch it, * so we don't check or report it here. * * Process Explanation: * Just before this function is called, the backward-branching * token for the "LOOP" variant that ends the control-structure * was written to the FCode Output buffer. * It needs an FCode-offset for a backward-branch targeted just * after its corresponding "DO" variant and the FCode-offset * associated therewith. * That "DO" variant's associated FCode-offset is targeted to * the token that follows the one for this "LOOP" variant * and its FCode-offset. * Make sure there are two DO C-S Tag entries on the Control Stack. * Resolve the backward-branch, matching your target to the first * C-S Tag for DO * Then resolve the forward-branch, targeting to your new OPC * position, and also making sure you match the DO C-S Tag. * We keep track of do_loop_depth for other error-detection * by decrementing it; make sure it doesn't go below zero. * Don't bother resolving the forward-branch if we underflowed * the "Control Stack" trying to resolve the backward-branch. * If the two top C-S Tag entries are not for a DO statement, the * matchup_two_control_structures() routine will consume both * or up to two of them, and we will place a dummy offset of * zero to follow-up the backward-branching token that has * already been written. * * Extraneous Remarks: * This is only a little more complicated to describe * than to code... ;-) * **************************************************************************** */ void resolve_loop( void ) { if ( INVERSE( matchup_two_control_structures( DO_CSTAG, DO_CSTAG) ) ) { emit_offset( 0 ); }else{ not_cs_underflow = TRUE; didnt_print_otl = TRUE; not_consuming_two = FALSE; resolve_backward( DO_CSTAG); if ( not_cs_underflow ) { resolve_forward( DO_CSTAG); } if ( do_loop_depth > 0 ) do_loop_depth--; not_consuming_two = TRUE; didnt_print_otl = TRUE; /* Might have gotten cleared */ } } /* ************************************************************************** * * Function name: emit_case * Synopsis: All the actions when CASE is encountered * * Associated FORTH word: CASE * * Inputs: * Parameters: NONE * * Outputs: * Returned Value: NONE * Items Pushed onto Control-Stack: * Top: N_OFs=0...CASE_CSTAG * (Datum is 0 , Initial count of OF .. ENDOF pairs) * FCode Output buffer: * Token for start of a CASE structure -- b(case) * Does not require an FCode-offset. * **************************************************************************** */ void emit_case( void ) { push_cstag( CASE_CSTAG, 0); emit_token("b(case)"); } /* ************************************************************************** * * Function name: emit_of * Synopsis: All the actions when OF is encountered * * Associated FORTH word: OF * * Inputs: * Parameters: NONE * Control-Stack Items: * Top: N_OFs...CASE_CSTAG * (Datum is OF-count, number of OF .. ENDOF pairs) * {Next and beyond}: {Endof_FORw_ENDOF}1..n_ofs * { Repeat for OF-count number of times } * * Outputs: * Returned Value: NONE * Control-Stack, 1 Item Pushed, 1 modified: * Top: Of_FORw_OF * Next: N_OFs+1...CASE_CSTAG * (Datum has been incremented) * {3rd and beyond}: {Endof_FORw_ENDOF}1..n_ofs * { Repeat for 1 through the un-incremented OF-count } * (Same as Next etcetera at input-time.) * FCode Output buffer: * Token for OF statement -- b(of) -- followed by * place-holder FCode-offset of zero * * Error Detection: * Matchup CASE-cstag before incrementing OF-count * * Process Explanation: * Main difference between this implementation and that outlined * in "the book" (see below) is that we do not directly use * the routine for the IF statement's flow-control; we will * use a different CSTAG for better mismatch detection. * * Extraneous Remarks: * This is a "by the book" (ANSI Forth spec, section A.3.2.3.2) * implementation (mostly). Incrementing the OF-count here, * after we've matched up the CSTAG, gives us (and the user) * just a little bit more protection... * **************************************************************************** */ void emit_of( void ) { if ( matchup_control_structure( CASE_CSTAG ) ) { emit_token("b(of)"); /* * See comment-block about "Control-Stack" Diagram Notation * early on in this file. * */ /* ( {Endof_FORw_ENDOF}1..n_ofs N_OFs...CASE_CSTAG -- ) */ /* Increment the OF-count . */ (control_stack->cs_datum)++; /* ( {Endof_FORw_ENDOF}1..n_ofs N_OFs+1...CASE_CSTAG -- ) */ mark_forward_branch( OF_CSTAG ); /* ( -- {Endof_FORw_ENDOF}1..n_ofs N_OFs+1...CASE_CSTAG Of_FORw_OF ) */ } /* Leave the CSTAG-Group on the "Control-Stack" . */ } /* ************************************************************************** * * Function name: emit_endof * Synopsis: All the actions when ENDOF is encountered * * Associated FORTH word: ENDOF * * Inputs: * Parameters: NONE * Control-Stack Items: * Top: Of_FORw_OF * Next: N_OFs+1...CASE_CSTAG * (Datum has been incremented) * {3rd and beyond}: {Endof_FORw_ENDOF}1..n_ofs * { Repeat for 1 through the un-incremented OF-count ) * * Outputs: * Returned Value: NONE * Control-Stack, 1 Item Popped, 1 new Item Pushed. * Top: N_OFs...CASE_CSTAG * (The count itself is unchanged from input-time, but * the number of {Endof_FORw_ENDOF} CSTAG-Groups * has caught up with this number, so it is * no longer notated as " + 1 "). * {Next and beyond}: {Endof_FORw_ENDOF}1..n_ofs * { Repeat for 1 through the updated OF-count ) * FCode Output buffer: * Token for ENDOF statement -- b(endof) -- followed by * place-holder FCode-offset of zero. Then the space reserved * for the FCode-offset of the forward-branch associated * with the "OF" statement is filled in so that it reaches * the token just after the "ENDOF" statement's FCode-offset. * * Error Detection: * If control-stack depth is not at least 2, CS underflow ERROR * and no further action. * Routine that resolves the forward-branch checks for matchup error. * **************************************************************************** */ void emit_endof( void ) { if ( control_stack_size_test( 2) ) { emit_token("b(endof)"); /* See "Control-Stack" Diagram Notation comment-block */ /* Stack-diagrams might need to be split across lines. */ /* ( {Endof_FORw_ENDOF}1..n_ofs N_OFs+1...CASE_CSTAG ... * ... Of_FORw_OF -- ) */ mark_forward_branch(ENDOF_CSTAG); /* ( -- {Endof_FORw_ENDOF}1..n_ofs N_OFs+1...CASE_CSTAG ... * ... Of_FORw_OF {Endof_FORw_ENDOF}n_ofs+1 ) */ control_structure_swap(); /* ( -- {Endof_FORw_ENDOF}1..n_ofs N_OFs+1...CASE_CSTAG ... * ... {Endof_FORw_ENDOF}n_ofs+1 Of_FORw_OF ) */ resolve_forward( OF_CSTAG ); /* ( -- {Endof_FORw_ENDOF}1..n_ofs N_OFs+1...CASE_CSTAG ... * ... {Endof_FORw_ENDOF}n_ofs+1 ) */ control_structure_swap(); /* ( -- {Endof_FORw_ENDOF}1..n_ofs ... * ... {Endof_FORw_ENDOF}n_ofs+1 ... * ... N_OFs+1...CASE_CSTAG ) */ /* The number of ENDOF-tagged Forward-Marker pairs has now * caught up with the incremented OF-count; therefore, * we can notate the above as: * * ( {Endof_FORw_ENDOF}1..n_ofs N_OFs CASE_CSTAG ) * * and we are ready for another OF ... ENDOF pair, * or for the ENDCASE statement. */ } } /* ************************************************************************** * * Function name: emit_endcase * Synopsis: All the actions when ENDCASE is encountered * * Associated FORTH word: ENDCASE * * Inputs: * Parameters: NONE * Control-Stack Items: * Top: N_OFs...CASE_CSTAG * (Datum is OF-count, number of OF .. ENDOF pairs) * {Next and beyond}: {Endof_FORw_ENDOF}1..n_ofs * { Repeat for OF-count number of times } * * Outputs: * Returned Value: NONE * Control-Stack, # of Items Popped: OF-count + 1 * FCode Output buffer: * Token for ENDCASE statement -- b(endcase) * Then the spaces reserved for the FCode-offsets of all the * forward-branches associated with the OF-count number * of ENDOF statements are filled in so that they reach * the token just after this "ENDCASE" statement. * * Error Detection: * Routine that resolves the forward-branch checks for matchup error * for each forward-branch filled in, plus the matchup routine * checks before the OF-count is retrieved. * * Process Explanation: * Retrieve the OF-count and resolve that number of ENDOF statements * * Extraneous Remarks: * The setup makes coding this routine appear fairly simple... ;-} * **************************************************************************** */ void emit_endcase( void ) { unsigned long n_endofs ; if ( matchup_control_structure( CASE_CSTAG) ) { int indx; emit_token("b(endcase)"); n_endofs = control_stack->cs_datum; for ( indx = 0 ; indx < n_endofs ; indx++ ) { /* Because matchup_control_structure doesn't pop the * control-stack, we have the N_OFs...CASE_CSTAG * item on top of the Endof_FORw_ENDOF item we * want to resolve. We need to keep it there so * the POP is valid for the other path as well * as at the end of this one. * So we SWAP to get at the Endof_FORw_ENDOF item. */ control_structure_swap(); resolve_forward( ENDOF_CSTAG); } } pop_cstag(); } /* ************************************************************************** * * Function name: control_struct_incomplete * Synopsis: Print a Message of given severity with origin info for * a control-structure that has not been completed. * * Inputs: * Parameters: * c_s_entry Control-structure about which to display * severity Severity of the messages to display. * call_cond String identifying Calling Condition; * used in the message. * * Outputs: * Returned Value: NONE * * Printout: * Message of given severity... * * Process Explanation: * The calling routine will be responsible for all filtering of * duplicate structures and the like. This routine will * simply display a message. * **************************************************************************** */ static void control_struct_incomplete( int severity, char *call_cond, cstag_group_t *c_s_entry) { tokenization_error ( severity, "%s before completion of %s" , call_cond, strupr(c_s_entry->cs_word)); where_started( c_s_entry->cs_inp_fil, c_s_entry->cs_line_num ); } /* ************************************************************************** * * Function name: announce_control_structs * Synopsis: Print a series of Messages (of severity as specified) * announcing that the calling event is occurring * in the context of Control-Flow structure(s), * back to the given limit. Leave the control * structures in effect. * * Inputs: * Parameters: * severity Severity of the messages to display. * call_cond String identifying Calling Condition; * used in the message. * abs_token_limit Limit, in terms of abs_token_no * Local Static Variables: * control_stack Pointer to "Top" of "Control-Stack" * * Outputs: * Returned Value: NONE * Printout: * A Message for each unresolved Control-Flow structure. * **************************************************************************** */ void announce_control_structs( int severity, char *call_cond, unsigned int abs_token_limit) { cstag_group_t *cs_temp = control_stack; while ( cs_temp != NULL ) { if ( cs_temp->cs_abs_token_num < abs_token_limit ) { break; } if ( cs_temp->cs_not_dup ) { control_struct_incomplete( severity, call_cond, cs_temp ); } cs_temp = cs_temp->prev; } } /* ************************************************************************** * * Function name: clear_control_structs_to_limit * Synopsis: Clear items from the "Control-Stack" back to the given * limit. Print error-messages with origin info for * control-structures that have not been completed. * * Inputs: * Parameters: * call_cond String identifying Calling Condition; * used in the Error message. * abs_token_limit Limit, in terms of abs_token_no * Global Variables: * control_stack_depth Number of items on "Control-Stack" * control_stack Pointer to "Top" of "Control-Stack" * Control-Stack Items: * The cs_inp_fil and cs_line_num tags of any item cleared * from the "Control-Stack" are used in error-messages. * * Outputs: * Returned Value: * Global Variables: * do_loop_depth Decremented when "DO" item cleared. * control_stack_depth Decremented by called routine. * Control-Stack, # of Items Popped: As many as go back to given limit * Memory Freed * By called routine. * * Error Detection: * Any item on the "Control-Stack" represents a Control-Structure * that was not completed when the Calling Condition was * encountered. Error; identify the origin of the structure. * No special actions if noerrors is set. * * Process Explanation: * The given limit corresponds to the value of abs_token_no at * the time the colon-definition (or whatever...) was created. * Any kind of Control-Structure imbalance at the end of the * colon-definition is an error and the entries must be cleared, * but the colon-definition may have been created inside nested * interpretation-time Control-Structures, and those must be * preserved. * * Of course, if this routine is called with a given limit of zero, * that would mean all the entries are to be cleared. That will * be the way clear_control_structs() is implemented. * We control the loop by the cs_abs_token_num field, but also * make sure we haven't underflowed control_stack_depth * We skip messages and other processing for items that are duplicates * of others, based on the cs_not_dup field. * If the cs_tag field is DO_CSTAG we decrement do_loop_depth * The pop_cstag() routine takes care of the rest. * * Extraneous Remarks: * This is a retrofit; necessary because we now permit definitions * to occur inside interpretation-time Control-Structures. Calls * to clear_control_structs() are already scattered around... * **************************************************************************** */ void clear_control_structs_to_limit( char *call_cond, unsigned int abs_token_limit) { while ( control_stack_depth > 0 ) { if ( control_stack->cs_abs_token_num < abs_token_limit ) { break; } if ( control_stack->cs_not_dup ) { control_struct_incomplete( TKERROR, call_cond, control_stack ); if ( control_stack->cs_tag == DO_CSTAG) do_loop_depth--; } pop_cstag(); } } /* ************************************************************************** * * Function name: clear_control_structs * Synopsis: Make sure the "Control-Stack" is cleared, and print * error-messages (giving origin information) for * control-structures that have not been completed. * * Inputs: * Parameters: * call_cond String identifying Calling Condition; * used in the Error message. * Global Variables: * control_stack_depth Number of items on "Control-Stack" * control_stack Pointer to "Top" of "Control-Stack" * Control-Stack Items: * The cs_inp_fil and cs_line_num tags of any item found on * the "Control-Stack" are used in error-messages. * * Outputs: * Returned Value: NONE * Global Variables: * control_stack_depth Reset to zero. * do_loop_depth Reset to zero. * Control-Stack, # of Items Popped: All of them * * Error Detection: * Any item on the "Control-Stack" represents a Control-Structure * that was not completed when the Calling Condition was * encountered. Error; identify the origin of the structure. * No special actions if noerrors is set. * * Process Explanation: * Filter the duplicate messages caused by structures (e.g., DO) * that place two entries on the "Control-Stack" by testing * the cs_not_dup field of the "Top" "Control-Stack" item, * which would indicate double-entry... * * Extraneous Remarks: * This is called before a definition of any kind, and after a * colon-definition. Flow-control constructs should *never* * be allowed to cross over between immediate-execution mode * and compilation mode. Likewise, not between device-nodes. * Also, at the end of tokenization, there should not be any * unresolved flow-control constructs. * **************************************************************************** */ void clear_control_structs( char *call_cond) { clear_control_structs_to_limit( call_cond, 0); }