/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
 * Copyright by The HDF Group.                                               *
 * Copyright by the Board of Trustees of the University of Illinois.         *
 * All rights reserved.                                                      *
 *                                                                           *
 * This file is part of HDF.  The full HDF copyright notice, including       *
 * terms governing use, modification, and redistribution, is contained in    *
 * the COPYING file, which can be found at the root of the source code       *
 * distribution tree, or in https://support.hdfgroup.org/ftp/HDF/releases/.  *
 * If you do not have access to either file, you may request a copy from     *
 * help@hdfgroup.org.                                                        *
 * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */

/* ------ he-cntrl.c ------
   This file contains much of the control mechanisms for HDFed
   - Many of the command line functions
   - The parsing functions
   - predicate handling
 */

#include "he.h"

/* --- HEif --- executes commands if predicates are satisfied */
int
HEif(HE_CMD *cmd)
{
    HE_PRED *pred;    /* predicates */
    HE_CMD  *cmdTail; /* last cmd we've seen in the sublist */

    if (cmd->argc == 2 && !strcmp(cmd->argv[1], "-help")) {
        puts("if [<predicates>]");
        puts("  <commands>*");
        puts("end");
        puts("\tExecutes commands if predicates are satisfied by element");
        return HE_OK;
    }

    /* parse the predicates on this command */
    pred = parsePred(cmd->argc, cmd->argv);
    if (!pred)
        return FAIL;

    /* execute the sub list only is the predicates are satisfied */
    if (satPred(currDesc, pred)) {
        /* go through sub-list until an end is encountered */
        for (cmdTail = cmd->sub; cmdTail && strcmp(cmdTail->argv[0], "end"); cmdTail = cmdTail->next)
            if (cmdTail->func)
                he_status = (*cmdTail->func)(cmdTail);
            else {
                fprintf(stderr, "Unrecognized command: %s\n", cmd->argv[0]);
                return FAIL;
            }
    }
    return HE_OK;
}

/* --- HEselect --- step through all the elements in a file and execute if
   predicates are satisfied */
int
HEselect(HE_CMD *cmd)
{
    int      t_currDesc; /* tmp var */
    HE_PRED *pred;       /* predicate structure */
    HE_CMD  *cmdTail;    /* last cmd we've seen in the sublist */

    if (cmd->argc == 2 && !strcmp(cmd->argv[1], "-help")) {
        puts("select [<predicates>]");
        puts("  <commands>*");
        puts("end");
        puts("\tSteps through all elements in the file that satisfies the");
        puts("\tpredicates and execute the commands on them.");
        return HE_OK;
    }

    /* generate predicate structure for this predicate list */
    pred = parsePred(cmd->argc, cmd->argv);
    if (!pred)
        return FAIL;

    /* save the curr desc index */
    t_currDesc = he_currDesc;

    /* step through all elements */
    for (he_currDesc = 0; he_currDesc < he_numDesc; he_currDesc++)
        if (currTag != DFTAG_NULL && satPred(currDesc, pred)) {
            for (cmdTail = cmd->sub; strcmp(cmdTail->argv[0], "end"); cmdTail = cmdTail->next)
                if (cmdTail->func)
                    he_status = (*cmdTail->func)(cmdTail);
                else {
                    fprintf(stderr, "Unrecognized command: %s\n", cmdTail->argv[0]);
                    he_status = FAIL;
                }
        }

    /* restore he_currDesc */
    he_currDesc = t_currDesc;

    return HE_OK;
}

/* --- move to the next item --- */

extern HE_PRED *he_predicates;

int
HEnext(HE_CMD *cmd)
{
    int      tmp;
    HE_PRED *predicates;

    if (cmd->argc == 2 && !strcmp(cmd->argv[1], "-help")) {
        puts("next [<predicates>]");
        puts("\tMove to the next element that satisfies the predicate");
        return HE_OK;
    }

    if (!fileOpen()) {
        noFile();
        return HE_FAIL;
    }

    predicates = parsePred(cmd->argc, cmd->argv);

    /* the following code assumes that parsePred() returns NULL if error, */
    /* a predicate struct with no key if empty predicate list */
    if (!predicates)
        return HE_FAIL;

    /* replace this only if it is non-empty */
    if (predicates[0].key != 0) {
        free(he_predicates);
        he_predicates = predicates;
    }

    tmp = he_currDesc;
    do {
        if (tmp >= he_numDesc - 1) {
            fprintf(stderr, "Reached end of file. Not moved.\n");
            return HE_FAIL;
        }
        tmp++;
    } while (he_desc[tmp].tag == DFTAG_NULL || !satPred(he_desc + tmp, he_predicates));

    he_currDesc = tmp;

    return HE_OK;
}

/* ---------- Move to previous item -------------- */

int
HEprev(HE_CMD *cmd)
{
    int      tmp;
    HE_PRED *predicates;

    if (cmd->argc == 2 && !strcmp(cmd->argv[1], "-help")) {
        puts("prev [<predicates>]");
        puts("\tMove to the next element that satisfies the predicate");
        return HE_OK;
    }

    if (!fileOpen()) {
        noFile();
        return HE_FAIL;
    }

    predicates = parsePred(cmd->argc, cmd->argv);

    /* the following code assumes that parsePred() returns NULL if error,
       a predicate struct with no key if empty predicate list */
    if (!predicates)
        return HE_FAIL;

    if (predicates[0].key != 0) {
        free(he_predicates);
        he_predicates = predicates;
    }

    tmp = he_currDesc;
    do {
        if (tmp <= 0) {
            fprintf(stderr, "Reached beginning of file. Not moved.\n");
            return HE_FAIL;
        }
        tmp--;
    } while (he_desc[tmp].tag == DFTAG_NULL || !satPred(he_desc + tmp, he_predicates));
    he_currDesc = tmp;

    return HE_OK;
}

/* ----------- routines to call od on some objects ----------- */

int
HEdump(HE_CMD *cmd)
{
    int   i;
    int   offset = 0, raw = 0;
    char  format[] = "-o";
    int32 length   = 0; /* zero is special, means all */

    for (i = 1; i < cmd->argc; i++)
        if (cmd->argv[i][0] == '-')
            switch (findOpt(cmd->argv[i] + 1)) {
                case HE_HELP:
                    printf("dump [-offset <offset>] [-length <len>]\n");
                    printf("\t[-decimal|-short|-byte|-hexadecimal|-float|-double|-ascii|\n");
                    printf("\t[-udecimal|-ushort|-octal|]\n");
                    printf("\tDisplay the contents of the current object\n");
                    printf("\t-offset            Start offset\n");
                    printf("\t-length            Length (bytes) to look at\n");
                    printf("\t-decimal           Decimal format [32 bit integers]\n");
                    printf("\t-short             Decimal format   [16 bit integers]\n");
                    printf("\t-byte              Decimal format    [8 bit integers]\n");
                    printf("\t-hexadecimal       Hexadecimal format\n");
                    printf("\t-float             Float format   [32 bit floats]\n");
                    printf("\t-double            Float format  [64 bit floats]\n");
                    printf("\t-ascii             Ascii format\n");
                    printf("\t-udecimal          Unsigned Decimal format [32 bit integers]\n");
                    printf("\t-ushort            Unsigned Decimal format   [16 bit integers]\n");
                    printf("\t-octal             Octal format [Default]\n");
                    return HE_OK;
                case HE_OFFSET:
                    offset = atoi(cmd->argv[++i]);
                    break;
                case HE_LENGTH:
                    length = atoi(cmd->argv[++i]);
                    if (length <= 0) {
                        fprintf(stderr, "Illegal length: %s, ignored.\n", cmd->argv[i]);
                        length = 0;
                    }
                    break;
                case HE_DECIMAL:
                    strcpy(format, "-i");
                    break;
                case HE_UDECIMAL:
                    strcpy(format, "-d");
                    break;
                case HE_SHORT:
                    strcpy(format, "-j");
                    break;
                case HE_USHORT:
                    strcpy(format, "-s");
                    break;
                case HE_BYTE:
                    strcpy(format, "-b");
                    break;
                case HE_OCTAL:
                    strcpy(format, "-o");
                    break;
                case HE_HEX:
                    strcpy(format, "-x");
                    break;
                case HE_FLOAT:
                    strcpy(format, "-f");
                    break;
                case HE_DOUBLE:
                    strcpy(format, "-e");
                    break;
                case HE_ASCII:
                    strcpy(format, "-a");
                    break;
                case HE_RAW:
                    raw = DFNT_NATIVE;
                    break;
                case HE_NOTFOUND:
                    unkOpt(cmd->argv[i]);
                    return HE_FAIL;
                case HE_AMBIG:
                    ambigOpt(cmd->argv[i]);
                    return HE_FAIL;
                default:
                    irrOpt(cmd->argv[i]);
                    return HE_FAIL;
            }
        else {
            unkArg(cmd->argv[i]);
            return HE_FAIL;
        }
    return HEIdump(length, offset, format, raw);
}

#define MAX_LINE 60

/*
 * Run 'od' on a segment of the current data element
 */
int
HEIdump(int32 length, int offset, char *format, int raw_flag)
{
    int32 eltLength;
    int32 i;
    int   len = 0;
    char *data;

    if (!fileOpen()) {
        noFile();
        return HE_FAIL;
    }

    eltLength = getElement(he_currDesc, &data);
    if (eltLength <= 0) {
        fprintf(stderr, "Unable to get element.\n");
        return HE_FAIL;
    }

    /* adjust the offset, negative offset implies starting from end. then
       check to see if offset is in range */
    if (offset < 0)
        offset += (int)eltLength;
    if (offset < 0 || offset > eltLength) {
        fprintf(stderr, "Illegal offset. Setting offset to 0.\n");
        offset = 0;
    }

    /* adjust the length if it falls beyond the end of the element */
    if (length == 0 || length > (eltLength - offset))
        length = eltLength - offset;

    /*
     * Dump the data to the console
     */

    switch (format[1]) {

        case 'i': {
            int32 *idata;
            idata = (int32 *)malloc(length / 4 * sizeof(int32));

            DFKconvert((void *)(data + offset), (void *)idata, DFNT_INT32 | raw_flag, length / 4, DFACC_READ,
                       0, 0);
            printf("%8d: ", offset);
            for (i = 0; i < length / 4; i++) {
                printf("%11d ", (int)idata[i]);
                if (++len > 4) {
                    len = 0;
                    printf("\n%8d: ", (int)(offset + (i + 1) * 4));
                }
            }
            printf("\n");
            free(idata);
        } break;

        case 'd': {
            uint32 *idata;
            idata = (uint32 *)malloc(length / 4 * sizeof(int32));

            DFKconvert((void *)(data + offset), (void *)idata, DFNT_UINT32 | raw_flag, length / 4, DFACC_READ,
                       0, 0);
            printf("%8d: ", offset);
            for (i = 0; i < length / 4; i++) {
                printf("%11u ", (int)idata[i]);
                if (++len > 4) {
                    len = 0;
                    printf("\n%8d: ", (int)(offset + (i + 1) * 4));
                }
            }
            printf("\n");
            free(idata);
        } break;
        case 'j': {
            int16 *sdata;
            sdata = (int16 *)malloc(length / 2 * sizeof(int16));
            DFKconvert((void *)(data + offset), (void *)sdata, DFNT_INT16 | raw_flag, length / 2, DFACC_READ,
                       0, 0);

            printf("%8d: ", offset);
            for (i = 0; i < length / 2; i++) {
                printf("%10d ", sdata[i]);
                if (++len > 5) {
                    len = 0;
                    printf("\n%8d: ", (int)(offset + (i + 1) * 2));
                }
            }
            printf("\n");
            free(sdata);
        } break;

        case 's': {
            uint16 *sdata;
            sdata = (uint16 *)malloc(length / 2 * sizeof(uint16));

            DFKconvert((void *)(data + offset), (void *)sdata, DFNT_UINT16 | raw_flag, length / 2, DFACC_READ,
                       0, 0);
            printf("%8d: ", offset);
            for (i = 0; i < length / 2; i++) {
                printf("%10d ", sdata[i]);
                if (++len > 5) {
                    len = 0;
                    printf("\n%8d: ", (int)(offset + (i + 1) * 2));
                }
            }
            printf("\n");
            free(sdata);
        } break;

        case 'b': {
            uint8 *bdata;
            bdata = (uint8 *)malloc(length);

            DFKconvert((void *)(data + offset), (void *)bdata, DFNT_UINT8 | raw_flag, length, DFACC_READ, 0,
                       0);
            printf("%8d: ", offset);
            for (i = 0; i < length; i++) {
                printf("%6d ", bdata[i]);
                if (++len > 7) {
                    len = 0;
                    printf("\n%8d: ", (int)(offset + (i + 1)));
                }
            }
            printf("\n");
            free(bdata);
        } break;

        case 'x': {
            int   *idata;
            size_t sizeint;

            sizeint = sizeof(int);
            idata   = (int *)malloc((size_t)(length / 4 * sizeint));
            DFKconvert((void *)(data + offset), (void *)idata, DFNT_NINT32 | raw_flag, length / 4, DFACC_READ,
                       0, 0);
            printf("%8d: ", offset);
            for (i = 0; i < length / sizeint; i++) {
                printf("%10x ", idata[i]);
                if (++len > 5) {
                    len = 0;
                    printf("\n%8d: ", (int)(offset + (i + 1) * sizeint));
                }
            }
            printf("\n");
            free(idata);
        } break;

        case 'o': {
            int   *idata;
            size_t sizeint;

            sizeint = sizeof(int);
            idata   = (int *)malloc((size_t)(length / 4 * sizeint));
            DFKconvert((void *)(data + offset), (void *)idata, DFNT_NINT32 | raw_flag, length / 4, DFACC_READ,
                       0, 0);
            printf("%8d: ", offset);
            for (i = 0; i < length / sizeint; i++) {
                printf("%10o ", idata[i]);
                if (++len > 4) {
                    len = 0;
                    printf("\n%8d: ", (int)(offset + (i + 1) * sizeint));
                }
            }
            printf("\n");
            free(idata);
        } break;

        case 'a': {
            char *cdata;
            cdata = (char *)(data + offset);
            printf("%8d: ", offset);
            for (i = 0; i < length; i++) {
                if (cdata[i] != '\0')
                    printf("%c", cdata[i]);
                else
                    printf(" ");
                if (++len > 40) {
                    len = 0;
                    printf("\n%8d: ", (int)(offset + (i + 1)));
                }
            }
            printf("\n");
        } break;

        case 'f': {
            float32 *fdata;
            fdata = (float32 *)malloc(length / 4 * sizeof(float32));

            DFKconvert((void *)(data + offset), (void *)fdata, DFNT_FLOAT32 | raw_flag, length / 4,
                       DFACC_READ, 0, 0);

            printf("%8d: ", offset);
            for (i = 0; i < length / 4; i++) {
                printf("%15e", (double)fdata[i]);
                if (++len > 3) {
                    len = 0;
                    printf("\n%8d: ", (int)(offset + (i + 1) * 4));
                }
            }
            printf("\n");
            free(fdata);
        } break;

        case 'e': {
            float64 *fdata;
            fdata = (float64 *)malloc(length / 8 * sizeof(float64));

            DFKconvert((void *)(data + offset), (void *)fdata, DFNT_FLOAT64 | raw_flag, length / 8,
                       DFACC_READ, 0, 0);

            printf("%8d: ", offset);
            for (i = 0; i < length / 8; i++) {
                printf("%30e", fdata[i]);
                if (++len > 1) {
                    len = 0;
                    printf("\n%8d: ", (int)(offset + (i + 1) * 8));
                }
            }
            printf("\n");
            free(fdata);
        } break;

        default:
            printf("Doing the default thang\n");
            break;
    }

    free(data);

    return HE_OK;
}

/* ------------------ Print 'info' ----------------- */

int
HEinfo(HE_CMD *cmd)
{
    int i;
    int all     = NO;
    int longout = NO;
    int group   = NO;
    int label   = NO;

    for (i = 1; i < cmd->argc; i++)
        if (cmd->argv[i][0] == '-')
            switch (findOpt(cmd->argv[i] + 1)) {
                case HE_HELP:
                    puts("info [-all] [-long] [-group] [-label]");
                    puts("\t-all\t\tShow info for all elements in file");
                    puts("\t-long\t\tShow more info");
                    puts("\t-group\t\tOrganize info in group(s)");
                    puts("\t-label\t\tShow label if any");
                    return HE_OK;
                case HE_LONGOUT:
                    longout = YES;
                    break;
                case HE_ALL:
                    all = YES;
                    break;
                case HE_LABEL:
                    label = YES;
                    break;
                case HE_DOGROUP:
                    group = YES;
                    break;
                case HE_NOTFOUND:
                    unkOpt(cmd->argv[i]);
                    return HE_FAIL;
                case HE_AMBIG:
                    ambigOpt(cmd->argv[i]);
                    return HE_FAIL;
                default:
                    irrOpt(cmd->argv[i]);
                    return HE_FAIL;
            }
        else {
            unkArg(cmd->argv[i]);
            return HE_FAIL;
        }
    return info(all, longout, group, label);
}

/*
 *Show info about data elements
 */
int
info(int all, int longout, int group, int label)
{
    int  idx;
    int  empty = 0;
    int  start, end;
    int  d;
    int *mark;

    if (!fileOpen()) {
        noFile();
        return HE_OK;
    }

    if (!group || ((!isGrp(currTag) && !all))) {
        if (all) {
            start = 0;
            end   = he_numDesc - 1;
        }
        else
            start = end = he_currDesc;

        /* The gcc optimizer thinks it can optimize away the conditional here,
         * which raises a strict-overflow warning. The volatile keyword
         * prevents optimization (possibly unrolling the for loop) and
         * squashes the warning.
         */
        for (volatile int i = start; i <= end; i++)
            if (he_desc[i].tag == DFTAG_NULL)
                empty++;
            else {
                if (all && i == he_currDesc)
                    printf("*");
                else
                    printf(" ");
                printf("(%d) ", i + 1); /* 1 based */
                infoDesc(i, longout, label);
            }

        if (empty > 0)
            printf("Empty (tag %d) : %d slots.\n", DFTAG_NULL, empty);
    }
    else {
        mark = (int *)calloc(he_numDesc, sizeof(int));

        if (all) {
            start = 0;
            end   = he_numGrp - 1;
        }
        else {
            if (he_numGrp == 0) {
                fprintf(stderr, "There is no group in this file.\n");
                return HE_FAIL;
            }
            start = end = currGrpNo;
        }
        for (int i = start; i <= end; i++) {
            printf("**Group %d:\n", i + 1); /* 1 based */
            idx = he_grp[i].desc;
            infoDesc(idx, longout, label);

            mark[idx] = YES;

            for (int j = 0; j < he_grp[i].size; j++)
                if ((d = findDesc(he_grp[i].ddList + j)) >= 0) {
                    mark[d] = 1;
                    infoDesc(d, longout, 0);
                }
                else
                    fprintf(stderr, "**Tag: %d, Ref: %d not in descriptors list!\n", he_grp[i].ddList[j].tag,
                            he_grp[i].ddList[j].ref);
        }
        if (all) {
            puts("\n**These do not belong to any group:");
            for (int i = 0; i < he_numDesc; i++)
                if (!mark[i]) {
                    if (he_desc[i].tag == DFTAG_NULL)
                        empty++;
                    else
                        infoDesc(i, longout, label);
                }

            if (empty > 0)
                printf("Empty (tag %d) : %d slots.\n", DFTAG_NULL, empty);
        }
    }
    return HE_OK;
}

void
infoDesc(int desc, int longout, int label)
{
    char *s;
    char *name;

    name = HDgettagsname(he_desc[desc].tag);
    if (!name)
        printf("\t%-30s: (Tag %d)", "Unknown Tag", he_desc[desc].tag);
    else {
        printf("\t%-30s: (Tag %d)", name, he_desc[desc].tag);
        free(name);
    }

    if (longout)
        printf("\n\tRef: %d, Offset: %ld, Length: %ld (bytes)\n", he_desc[desc].ref,
               (long)he_desc[desc].offset, (long)he_desc[desc].length);
    else
        printf(" Ref %d\n", he_desc[desc].ref);
    if (label) {
        getAnn(HE_LABEL, he_desc[desc].tag, he_desc[desc].ref, &s);
        if (s != NULL)
            printf("\tLabel: %s\n", s);
    }
}

/* ---------- HEdelete --- 'stub' function for delete */
int
HEdelete(HE_CMD *cmd)
{
    if (cmd->argc < 2)
        return delete (he_currDesc);
    else {
        if (cmd->argv[1][0] != '-') {
            unkArg(cmd->argv[1]);
            return HE_FAIL;
        }
        else
            switch (findOpt(cmd->argv[1] + 1)) {
                case HE_HELP:
                    puts("delete");
                    puts("\tDelete this element or group.");
                    return HE_OK;
                case HE_NOTFOUND:
                    unkOpt(cmd->argv[1]);
                    return HE_FAIL;
                case HE_AMBIG:
                    ambigOpt(cmd->argv[1]);
                    return HE_FAIL;
                default:
                    irrOpt(cmd->argv[1]);
                    return HE_FAIL;
            }
    }
}

/* delete -- deletes a group and its elts or an elt from current hdf file */
int delete (int curr)
{
    int ret;

    /* check if any file is open */
    if (!fileOpen()) {
        noFile();
        return HE_FAIL;
    }

    /* call the actual routine to do it, the update the descriptor list */
    ret = recurseDel(curr);
    updateDesc();

    return ret;
}

/* recurseDel -- this function recursively tries to delete some elts from
   a file. if the current elt is a group, it will call itself on the elts
   of the group. else, it will check if any group references the elt, and
   actually deletes it if there is no other references */
int
recurseDel(int curr)
{
    int d, currGrp;
    int i;

    if (isGrp(he_desc[curr].tag)) {
        /* if this is a group, do its elts then itself */

        /* find the index of the group */
        currGrp = desc2Grp(curr);

        /* step through the elts of this group */
        for (i = 0; i < he_grp[currGrp].size; i++) {
            d = findDesc(he_grp[currGrp].ddList + i);
            if (d >= 0) {
                /* null this so it will not report that this is a multiple
                 * copy of itself */
                he_grp[currGrp].ddList[i].tag = DFTAG_NULL;
                he_grp[currGrp].ddList[i].ref = 0;

                /* Try to delete this component */
                if (recurseDel(d) < 0)
                    return HE_FAIL;
            }
        }
        /* tried all components, now delete self */
        if (!hasReference(curr))
            if (deleteDesc(curr) < 0)
                return HE_FAIL;
    }
    else
        /* not a group, actually delete this only if there is no group
           referencing it */
        if (!hasReference(curr))
            if (deleteDesc(curr) < 0)
                return HE_FAIL;
    return HE_OK;
}

/* some char const for the get/parse routines */
#define CR      '\n'
#define SPACE   ' '
#define TAB     '\t'
#define QUOTE   '"'
#define BREAK   '\003' /* C-c */
#define ESCAPE  '\\'   /* Quote escape */
#define COMMENT '!'    /* Comment a line if first character */

/* max line size -- change this if you type longer than this in one line */
#define HE_LINE_SZ 512

/* command separator */
#define HE_SEPARATOR ';'

/* is this in batch mode or interactive? */
int he_batch = NO;

/* nesting when if/select is encountered */
int he_nestLevel = 0;

/* prompt is actually "he"<he_prompt><space> */
const char *he_prompt = ">";
#define he_nestChar '>'

/* table to associate command to the function --
   add additional functions anywhere in the table BEFORE the
   Marker {0,0} entry */
struct {
    const char *str;
    HE_FUNC     func;
} he_funcTab[] = {
    {"open", (HE_FUNC)HEopen},       {"close", (HE_FUNC)HEclose},   {"next", (HE_FUNC)HEnext},
    {"prev", (HE_FUNC)HEprev},       {"alias", (HE_FUNC)HEalias},   {"unalias", (HE_FUNC)HEunalias},
    {"display", (HE_FUNC)HEdisplay}, {"info", (HE_FUNC)HEinfo},     {"list", (HE_FUNC)HEinfo},
    {"if", (HE_FUNC)HEif},           {"select", (HE_FUNC)HEselect}, {"wait", (HE_FUNC)HEwait},
    {"delete", (HE_FUNC)HEdelete},   {"quit", (HE_FUNC)HEquit},     {"dump", (HE_FUNC)HEdump},
    {"getr8", (HE_FUNC)HEgetR8},     {"putr8", (HE_FUNC)HEputR8},   {"put", (HE_FUNC)HEput},
    {"revert", (HE_FUNC)HErevert},   {"write", (HE_FUNC)HEwrite},   {"annotate", (HE_FUNC)HEannotate},
    {"help", (HE_FUNC)HEhelp},       {"end", (HE_FUNC)0},
};

HE_FUNC
findFunc(char *fword)
{
    unsigned len;
    int      found = -1;

    len = strlen((const char *)fword);

    for (int i = 0; i < sizeof(he_funcTab) / sizeof(he_funcTab[0]); i++)
        if (!strncmp(he_funcTab[i].str, (const char *)fword, len)) {
            /* check for exact match */
            if (strlen(he_funcTab[i].str) == len)
                return he_funcTab[i].func;

            if (found < 0)
                found = (int)i;
            else {
                fprintf(stderr, "Ambiguous command: %s.\n", fword);
                return NULL;
            }
        }

    if (found < 0)
        return NULL;
    else
        return he_funcTab[found].func;
}

/* prompt -- printout prompt according to the nesting level */
void
prompt(void)
{

    if (!he_nestLevel)
        printf("hdfed%s ", he_prompt);
    else {
        int i;

        printf("     %s ", he_prompt);
        for (i = he_nestLevel; i; i--)
            putchar(he_nestChar);
        putchar(' ');
    }
}

/* reads a line of input into p */
/* Skips all initial spaces and empty commands */
/* always returns with at least a word in p, unless eof */
/* if eof and p is not empty, return HE_OK, else if no word, return EOF */
int
getLine(char *p)
{
    static int ch = 0;

    do {
        if (!he_batch && (ch != EOF))
            prompt();
        ch = getc(stdin);
        if (ch == COMMENT) {
            /* Skip this line */
            do
                ch = getchar();
            while ((ch != CR) && (ch != EOF));
        }
        else
            while ((ch == SPACE) || (ch == TAB) || (ch == HE_SEPARATOR))
                ch = getchar();
        if (ch == EOF)
            return EOF;
    } while (ch == CR);

    while ((ch != EOF) && (ch != CR))
        switch (ch) {
            case ESCAPE:
                ch = getchar();
                if (!(ch == CR))
                    *p++ = (char)ch;
                ch = getchar();
                break;
            case QUOTE:
                ch = getchar();
                while (ch != QUOTE) {
                    if (ch == ESCAPE)
                        ch = getchar();
                    *p++ = (char)ch;
                    ch   = getchar();
                }
                ch = getchar(); /* Skip over the QUOTE */
                break;
            case SPACE:
            case TAB:
                *p++ = SPACE;
                while ((ch == SPACE) || (ch == TAB))
                    ch = getchar();
                break;
            case HE_SEPARATOR:
                if (!isspace((int)*(p - 1)))
                    *p++ = SPACE;
                *p++ = HE_SEPARATOR;
                ch   = SPACE; /* Ensure next is a space */
                break;
            default:
                *p++ = (char)ch;
                ch   = getchar();
                break;
        }

    *p++ = '\0';
    return ch;
}

/* copy the next (space-delimited) word and advance the pointer as a
   side effect */
char *
nextWord(char **p)
{
    char    *word = NULL;
    char    *s    = NULL;
    char    *q    = NULL;
    unsigned len;

    q = *p;
    while (*q && isspace((int)*q))
        q++;
    if (!(*q)) {
        *p = q;
        return NULL;
    }

    s = q;
    while (*s && !isspace((int)*s))
        s++;
    len = (unsigned)(s - q);

    word = (char *)malloc(len + 1);
    strncpy(word, q, len);
    word[len] = '\0';

    *p = s;
    while (**p && (isspace((int)**p)))
        (*p)++;

    return word;
}

HE_CMD *
parseCmd(char **p)
{
    char   *word;
    HE_CMD *cmd;
    HE_CMD *aliasCmd;
    HE_CMD *cmdTail;

    if (!(**p))
        return NULL;

    cmd       = (HE_CMD *)calloc(1, sizeof(HE_CMD));
    cmd->next = cmd->sub = (HE_CMD *)NULL;
    cmd->argc            = 1;
    cmd->argv[0]         = nextWord(p);

    if ((aliasCmd = findAlias(cmd->argv[0])) != NULL)
        cmd = aliasCmd;
    else
        cmd->func = findFunc(cmd->argv[0]);

    if ((cmd->func == (HE_FUNC)HEalias) || (cmd->func == (HE_FUNC)HEwait)) {
        /* let the alias command handle the parsing */
        cmd->argv[1] = copyStr(*p);
        cmd->argc    = 2;

        **p = '\0';
    }
    else {
        cmdTail = cmd;
        while (cmdTail->next)
            cmdTail = cmdTail->next;

        for (word = nextWord(p); word && strcmp(word, ";"); word = nextWord(p), cmdTail->argc++)
            cmdTail->argv[cmdTail->argc] = word;

        while (**p && (isspace((int)**p) || (**p == ';')))
            (*p)++;
    }
    return cmd;
}

/* Inputs a line and returns cmd list of line */
HE_CMD *
parse(void)
{
    static char  line[HE_LINE_SZ];
    static char *ptr;
    int          notDone = 1;
    HE_CMD      *cmd;
    HE_CMD      *cmdTail;

    if (getLine(line) == EOF)
        return NULL;
    ptr = line;

    cmdTail = cmd = parseCmd(&ptr);
    while (cmdTail->next)
        cmdTail = cmdTail->next;

    while (notDone) {
        cmdTail->next = parseCmd(&ptr);
        notDone       = (cmdTail->next != NULL);
        while (cmdTail->next)
            cmdTail = cmdTail->next;
    }
    return cmd;
}

HE_CMD *
getCmd(void)
{
    static HE_CMD *cmdList;
    HE_CMD        *cmd;
    HE_CMD        *cmdTail;

    if (!cmdList)
        cmdList = parse();
    if (!cmdList)
        return NULL;

    cmd = cmdList;
    if (cmdList)
        cmdList = cmdList->next;
    cmd->next = (HE_CMD *)NULL; /* Cut off links since these will be */
    /* accessed later */

    if (cmd && ((cmd->func == (HE_FUNC)HEif) || (cmd->func == (HE_FUNC)HEselect)) &&
        !((cmd->argc > 1) && (cmd->argv[1][0] == '-') && (findOpt(cmd->argv[1] + 1) == HE_HELP))) {
        he_nestLevel++;

        cmd->sub = getCmd();
        for (cmdTail = cmd->sub; cmdTail && strcmp(cmdTail->argv[0], "end"); /* while != "end" */
             cmdTail = cmdTail->next)
            cmdTail->next = getCmd();

        he_nestLevel--;
    }
    return cmd;
}

#define HE_ALIAS_SZ 256

struct he_alias {
    char   *str;
    HE_CMD *cmd;
} he_aliasTab[HE_ALIAS_SZ];

int he_numAlias = 0;

int
setAlias(char *str, HE_CMD *cmd)
{
    int i;

    for (i = 0; i < he_numAlias; i++)
        if (!strcmp(str, he_aliasTab[i].str)) {
            he_aliasTab[i].cmd = cmd;
            return HE_OK;
        }
    if (he_numAlias == HE_ALIAS_SZ) {
        fprintf(stderr, "Alias table full.\n");
        return HE_FAIL;
    }
    he_aliasTab[he_numAlias].str   = str;
    he_aliasTab[he_numAlias++].cmd = cmd;

    return HE_OK;
}

HE_CMD *
mkDupCmd(HE_CMD *cmd)
{
    int     i;
    HE_CMD *dupCmd;

    dupCmd       = (HE_CMD *)calloc(1, sizeof(HE_CMD));
    dupCmd->func = cmd->func;
    dupCmd->argc = cmd->argc;
    dupCmd->next = dupCmd->sub = (HE_CMD *)NULL;
    for (i = 0; i < cmd->argc; i++)
        dupCmd->argv[i] = copyStr(cmd->argv[i]);

    return dupCmd;
}

HE_CMD *
findAlias(char *str)
{
    int     i;
    HE_CMD *cmd;
    HE_CMD *dupCmd;
    HE_CMD *cmdTail;

    for (i = 0; i < he_numAlias; i++)
        if (!strcmp(str, he_aliasTab[i].str)) {
            cmd    = he_aliasTab[i].cmd;
            dupCmd = mkDupCmd(cmd);

            cmd = cmd->next;
            for (cmdTail = dupCmd; cmd; cmd = cmd->next, cmdTail = cmdTail->next)
                cmdTail->next = mkDupCmd(cmd);

            return dupCmd;
        }
    return NULL;
}

int
HEunalias(HE_CMD *cmd)
{
    for (int a = 1; a < cmd->argc; a++)
        for (int i = 0; i < he_numAlias; i++)
            if (!strcmp(cmd->argv[a], he_aliasTab[i].str)) {
                he_numAlias--;
                for (int j = i; j < he_numAlias; j++) {
                    he_aliasTab[j].str = he_aliasTab[j + 1].str;
                    he_aliasTab[j].cmd = he_aliasTab[j + 1].cmd;
                }
                break;
            }
    return HE_OK;
}

void
printAlias(char *word, HE_CMD *cmd)
{
    printf("%s:", word);
    for (; cmd; cmd = cmd->next) {
        printf("\t");
        for (int j = 0; j < cmd->argc; j++)
            printf("%s ", cmd->argv[j]);
        puts("");
    }
}

int
HEalias(HE_CMD *cmd)
{
    char   *s;
    char   *word;
    int     i;
    HE_CMD *cmdTail;

    s    = cmd->argv[1];
    word = nextWord(&s);

    if (!word) {
        for (i = 0; i < he_numAlias; i++)
            printAlias(he_aliasTab[i].str, he_aliasTab[i].cmd);
        return HE_OK;
    }

    cmd = parseCmd(&s);
    if (!cmd) {
        cmd = findAlias(word);
        printAlias(word, cmd);
        return HE_OK;
    }
    for (cmdTail = cmd; cmdTail->next; cmdTail = cmdTail->next) /*EMPTY */
        ;
    while ((cmdTail->next = parseCmd(&s)) != NULL)
        for (; cmdTail->next; cmdTail = cmdTail->next) /*EMPTY */
            ;
    return setAlias(word, cmd);
}

HE_PRED *he_predicates;

/* resetPred -- for setting the he_predicates to point to a pred
   of only group, this is the default when a file is opened */
int
resetPred(void)
{
    free(he_predicates);

    he_predicates        = (HE_PRED *)calloc(2, sizeof(HE_PRED));
    he_predicates[0].key = HEK_GROUP;
    he_predicates[1].key = 0;

    return HE_OK;
}

struct {
    const char *str;
    int         key;
} he_keyTab[] = {
    {"!=", HEK_NEQUAL | HE_COMPARATOR},  {"<", HEK_LESST | HE_COMPARATOR},
    {"<=", HEK_LEQUAL | HE_COMPARATOR},  {"==", HEK_EQUAL | HE_COMPARATOR},
    {">", HEK_GRT | HE_COMPARATOR},      {">=", HEK_GEQUAL | HE_COMPARATOR},
    {"all", HEK_ALL | HE_PREDICATE},     {"any", HEK_ALL | HE_PREDICATE},
    {"ref", HEK_REF | HE_PREDICATE},     {"succeed", HEK_SUCCEED | HE_PREDICATE},
    {"fail", HEK_FAIL | HE_PREDICATE},   {"tag", HEK_TAG | HE_PREDICATE},
    {"group", HEK_GROUP | HE_PREDICATE},
    /* Finish this later */
};

int
findKey(char *word)
{
    unsigned len;
    int      found = -1;

    len = strlen(word);

    for (int i = 0; i < sizeof(he_keyTab) / sizeof(he_keyTab[0]); i++)
        if (!strncmp(he_keyTab[i].str, word, len)) {
            /* if this is an exact match, just return */
            if (strlen(he_keyTab[i].str) == len)
                return he_keyTab[i].key;
            if (found < 0)
                found = (int)i;
            else {
                fprintf(stderr, "Ambiguous: %s.\n", word);
                return HE_NOTFOUND;
            }
        }
    if (found < 0) {
        fprintf(stderr, "Predicate/comparator: %s not found.\n", word);
        return HE_NOTFOUND;
    }
    return he_keyTab[found].key;
}

int
isNumber(char *s)
{
    for (; *s; s++)
        if (!isdigit((int)*s))
            return NO;

    return YES;
}

#define HE_PRED_SZ HE_ARG_SZ

HE_PRED *
parsePred(int argc, char *argv[])
{
    HE_PRED *pred;
    int      predNum = -1;
    int      state   = 0;
    int      key     = 0;

    pred = (HE_PRED *)calloc(HE_PRED_SZ, sizeof(HE_PRED));

    for (int i = 1; i < argc; i++) {

        char *s = argv[i];

        while (*s) {
            char *tok = NULL;

            if (state != 2)
                tok = nextToken(&s);
            else
                tok = nextWord(&s);
            if (!tok)
                break;

            if (state != 2) {
                if ((key = findKey(tok)) == HE_NOTFOUND) {
                    free(pred);
                    return NULL;
                }
                free(tok);
            }

            switch (state) {
                case 0:
                    /* Ready to accept a predicate */
                    if (!(key & HE_PREDICATE)) {
                        fprintf(stderr, "Parse error: %s.\n", argv[i]);
                        free(pred);
                        return NULL;
                    }
                    pred[++predNum].key = key & ~(HE_PREDICATE | HE_COMPARATOR);
                    state               = 1;
                    break;

                case 1:
                    /* Can be a comparator for previous pred or a new predicate */
                    if (key & HE_PREDICATE) {
                        pred[++predNum].key = key & ~(HE_PREDICATE | HE_COMPARATOR);
                    }
                    else if (key & HE_COMPARATOR) {
                        pred[predNum].Comp = key & ~(HE_PREDICATE | HE_COMPARATOR);
                        state              = 2;
                    }
                    else {
                        fprintf(stderr, "Parse error: %s.\n", argv[i]);
                        free(pred);
                        return NULL;
                    }
                    break;

                case 2:
                    /* Looking for an argument */
                    if (isNumber(tok)) {
                        pred[predNum].argType = HE_NUMBER;
                        pred[predNum].arg.i   = atoi(tok);
                    }
                    else {
                        pred[predNum].argType = HE_STRING;
                        pred[predNum].arg.str = copyStr(tok);
                    }
                    state = 0;
                    free(tok);
                    break;

                default:
                    NOT_REACHED();
                    break;
            }
        }
    }
    pred[++predNum].key = 0;

    return pred;
}

int
satPred(DFdesc *desc, HE_PRED pred[])
{
    int i;

    if (!pred)
        return YES;
    for (i = 0; pred[i].key; i++) {
        switch (pred[i].key) {
            case HEK_ALL:
                return YES; /* Always satisfied */
            case HEK_GROUP:
                if (!isGrp(desc->tag))
                    return NO;
                break;
            case HEK_TAG:
                if (pred[i].argType != HE_NUMBER) {
                    fprintf(stderr, "Argument to tag predicate not a number.");
                    return NO;
                }
                if (!numCompare((int)desc->tag, pred[i].Comp, pred[i].arg.i))
                    return NO;
                break;
            case HEK_REF:
                if (pred[i].argType != HE_NUMBER) {
                    fprintf(stderr, "Argument to ref predicate not a number.");
                    return NO;
                }
                if (!numCompare((int)desc->ref, pred[i].Comp, pred[i].arg.i))
                    return NO;
                break;
            case HEK_SUCCEED:
                return (he_status == 0);
            case HEK_FAIL:
                return (he_status != 0);
            default:
                NOT_REACHED();
                break;
        }
    }

    return 1;
}

char *
nextToken(char **p)
{
    char *s, *q;
    char *tok;

    if (!(**p))
        return NULL;

    s = *p;

    if (isalnum((int)**p))
        while (isalnum((int)*s))
            s++;
    else
        while (*s && !isalnum((int)*s))
            s++;

    q = tok = (char *)malloc((s - (*p)) + 1);
    while (*p != s)
        *q++ = *(*p)++;
    *q = '\0';

    return tok;
}

int
numCompare(int n1, int Comp, int n2)
{
    switch (Comp) {
        case HEK_EQUAL:
            return (n1 == n2);

        case HEK_NEQUAL:
            return (n1 != n2);

        case HEK_GRT:
            return (n1 > n2);

        case HEK_GEQUAL:
            return (n1 >= n2);

        case HEK_LESST:
            return (n1 < n2);

        case HEK_LEQUAL:
            return (n1 <= n2);

        default:
            NOT_REACHED();
            break;
    }
    return NO;
}

/* end of cntrl.c */