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//{{{ Banner //============================================================================ // // cdlmisc.cxx // // Implementation of the various CDL utility member functions. // //============================================================================ //####COPYRIGHTBEGIN#### // // ---------------------------------------------------------------------------- // Copyright (C) 1998, 1999, 2000 Red Hat, Inc. // // This file is part of the eCos host tools. // // 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; either version 2 of the License, or (at your option) // any later version. // // 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., // 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. // // ---------------------------------------------------------------------------- // //####COPYRIGHTEND#### //============================================================================ //#####DESCRIPTIONBEGIN#### // // Author(s): bartv // Contact(s): bartv // Date: 1998/03/04 // Version: 0.01 // //####DESCRIPTIONEND#### //============================================================================ //}}} //{{{ #include's // ---------------------------------------------------------------------------- #include "cdlconfig.h" // Get the infrastructure types, assertions, tracing and similar // facilities. #include <cyg/infra/cyg_ass.h> #include <cyg/infra/cyg_trac.h> // <cdlcore.hxx> defines everything implemented in this module. // It implicitly supplies <string>, <vector> and <map> because // the class definitions rely on these headers. #include <cdlcore.hxx> // For access to the isdigit(), isupper(), tolower(), ... functions #include <cctype> // For access to sprintf(), specifically double to string conversions. #include <cstdio> // For access to strtod() #include <cstdlib> // strtod() involves errno... #include <cerrno> // For access to fmod() #include <cmath> // For access to DBL_DIG #include <cfloat> //}}} //{{{ Cdl::is_valid_xxx() // --------------------------------------------------------------------------- bool Cdl::is_valid_value_flavor(CdlValueFlavor data) { bool result = false; switch(data) { case CdlValueFlavor_None : case CdlValueFlavor_Bool : case CdlValueFlavor_BoolData : case CdlValueFlavor_Data : result = true; break; default: break; } return result; } bool Cdl::is_valid_value_source(CdlValueSource data) { bool result = false; switch(data) { case CdlValueSource_Default : case CdlValueSource_User : case CdlValueSource_Wizard : case CdlValueSource_Inferred : result = true; break; default: break; } return result; } // ---------------------------------------------------------------------------- // For now CDL names are restricted to what is acceptable to the C // preprocessor. This may cause problems in future, e.g. i18n. bool Cdl::is_valid_cdl_name(const std::string& name) { CYG_REPORT_FUNCNAMETYPE("Cdl::is_valid_cdl_name", "result %d"); bool result = is_valid_c_preprocessor_symbol(name); CYG_REPORT_RETVAL(result); return result; } bool Cdl::is_valid_c_preprocessor_symbol(const std::string& symbol) { CYG_REPORT_FUNCNAMETYPE("Cdl::is_valid_c_preprocessor_symbol", "result %d"); bool result = true; if ("" == symbol) { result = false; } else { // A valid preprocessor symbol should begin with either an underscore // or a letter. It should then be followed by some number of underscores, // letters, or digits. // // In some locales isalpha() may succeed for characters which are not // legal for C preprocessor symbols. Instead ASCII is assumed here. if (('_' != symbol[0]) && !(('a' <= symbol[0]) && (symbol[0] <= 'z')) && !(('A' <= symbol[0]) && (symbol[0] <= 'Z'))) { result = false; } else { for (unsigned int i = 1; i < symbol.size(); i++) { if (('_' != symbol[i]) && !(('a' <= symbol[i]) && (symbol[i] <= 'z')) && !(('A' <= symbol[i]) && (symbol[i] <= 'Z')) && !(('0' <= symbol[i]) && (symbol[i] <= '9'))) { result = false; break; } } } } CYG_REPORT_RETVAL(result); return result; } //}}} //{{{ Cdl::xxx_to_yyy() - strings, ints, doubles, ... // --------------------------------------------------------------------------- // Conversion routines between strings, integers, doubles, bools, ... // // Conversions to/from integers are complicated somewhat because the // data type in question is cdl_int. In the initial implementation this // is 64 bits. In the long term it will be arbitrary precision and // the conversion routines will need to be reimplemented. // // ASCII rather than EBCDIC is assumed. // // Some of the routines may fail, e.g. string to integer conversions. // Others are guaranteed to succeed. //{{{ string_to_integer() // ---------------------------------------------------------------------------- bool Cdl::string_to_integer(std::string data, cdl_int& target) { CYG_REPORT_FUNCNAMETYPE("Cdl::string_to_integer", "success %d"); bool negative = false; bool seen_plus = false; bool seen_minus = false; // Life is a bit easier if I can check for '\0' const char* ptr = data.c_str(); // Not essential but harmless. while (isspace(*ptr)) ptr++; if ('+' == *ptr) { if (seen_plus) { target = 0; CYG_REPORT_RETVAL(false); return false; } seen_plus = true; ptr++; } if ('-' == *ptr) { if (seen_minus) { target = 0; CYG_REPORT_RETVAL(false); return false; } seen_minus = true; negative = true; ptr++; } cdl_int acc = 0; if ('0' == *ptr) { // This happens sufficiently often to be worth a special case. if ('\0' == ptr[1]) { target = 0; CYG_REPORT_RETVAL(true); return true; } // Hex is always worth supporting. if (('x' == ptr[1]) || ('X' == ptr[1])) { ptr++; ptr++; if (!isxdigit(*ptr)) { CYG_REPORT_RETVAL(false); return false; } while (isxdigit(*ptr)) { cdl_int new_acc = acc * 16; if (isdigit(*ptr)) { new_acc += (*ptr - '0'); } else if (('a' <= *ptr) && (*ptr <= 'f')) { new_acc += (*ptr + 10 - 'a'); } else if (('A' <= *ptr) && (*ptr <= 'F')) { new_acc += (*ptr + 10 - 'A'); } else { CYG_FAIL("this platform's implementation of isxdigit() is broken"); } if (new_acc < acc) { CYG_REPORT_RETVAL(false); return false; } acc = new_acc; ptr++; } if ('\0' != *ptr) { CYG_REPORT_RETVAL(false); return false; } if (negative) { cdl_int new_acc = 0 - acc; if (new_acc > 0) { CYG_REPORT_RETVAL(false); return false; } else { acc = new_acc; } } target = acc; CYG_REPORT_RETVAL(true); return true; } // Octal? Oh well, might as well be complete. if (('0' <= ptr[1]) && (ptr[1] <= '7')) { ptr++; do { cdl_int new_acc = 8 * acc; new_acc += (*ptr - '0'); if (new_acc < acc) { CYG_REPORT_RETVAL(false); return false; } acc = new_acc; ptr++; } while (('0' <= *ptr) && (*ptr <= '7')); if ('\0' != *ptr) { CYG_REPORT_RETVAL(false); return false; } if (negative) { cdl_int new_acc = 0 - acc; if (new_acc > 0) { CYG_REPORT_RETVAL(false); return false; } else { acc = new_acc; } } target = acc; CYG_REPORT_RETVAL(true); return true; } // Drop through for the case of a decimal. } while(isdigit(*ptr)) { cdl_int new_acc = 10 * acc; new_acc += (*ptr - '0'); if (new_acc < acc) { CYG_REPORT_RETVAL(false); return false; } acc = new_acc; ptr++; } if ('\0' != *ptr) { CYG_REPORT_RETVAL(false); return false; } if (negative) { cdl_int new_acc = 0 - acc; if (new_acc > 0) { CYG_REPORT_RETVAL(false); return false; } else { acc = new_acc; } } target = acc; CYG_REPORT_RETVAL(true); return true; } //}}} //{{{ string_to_double() // ---------------------------------------------------------------------------- // There is no point in doing this the hard way, just use standard // library calls. // // There is an obvious question as to how much precision can get lost // doing the conversion to a string. In practice this should not matter // too much, since the expression handling code generally keeps the // original double precision lying around to be re-used. However it may // be desirable to keep the libcdl behaviour in synch with Tcl's // tcl_precision variable. bool Cdl::string_to_double(std::string value, double& target) { CYG_REPORT_FUNCNAMETYPE("Cdl::string_to_double", "success %d"); bool result = true; const char* start_ptr = value.c_str(); char* end_ptr; int old_errno = errno; errno = 0; double conv = strtod(start_ptr, &end_ptr); if (0 != errno) { CYG_ASSERT(ERANGE == errno, "standard-compliant C library"); result = false; } else if ('\0' != *end_ptr) { result = false; } else { target = conv; result = true; } errno = old_errno; CYG_REPORT_RETVAL(result); return result; } //}}} //{{{ string_to_bool() // ---------------------------------------------------------------------------- // Conversions to and from bools. The only real issue here is exactly // what strings should be accepted as synonyms for true and false. // It is not actually clear that these functions are useful. bool Cdl::string_to_bool(std::string data, bool& target) { CYG_REPORT_FUNCNAMETYPE("Cdl::string_to_bool", "success %d"); // Arguably there should be a precondition ( "" != data ) bool result = false; // What is truth ? if (( data == "1" ) || (data == "true") || ( data == "True") || (data == "TRUE") ) { result = true; target = true; } else if ((data == "0" ) || (data == "false") || (data == "False") || (data == "FALSE") ) { result = true; target = false; } CYG_REPORT_RETVAL(result); return result; } //}}} //{{{ integer_to_string() // ---------------------------------------------------------------------------- std::string Cdl::integer_to_string(cdl_int value, CdlValueFormat format) { std::string result; Cdl::integer_to_string(value, result, format); return result; } void Cdl::integer_to_string(cdl_int value, std::string& target, CdlValueFormat format) { CYG_REPORT_FUNCNAME("Cdl::integer_to_string"); CYG_REPORT_FUNCARG2XV((long) value, format); // Optimise this special case. if (0 == value) { if (CdlValueFormat_Hex == format) { target = "0x0"; } else { target = "0"; } CYG_REPORT_RETVAL(true); return; } // A local buffer to construct partial strings. This avoids // unnecessary std::string reallocation. // 64 bits and three bits at a time for octal numbers gives 21 digits, // plus spares for the leading '0' and the terminator. char local_buf[24]; char *local_ptr = &(local_buf[23]); *local_ptr-- = '\0'; if (CdlValueFormat_Hex == format) { // Output the data as 0x... with either 8 or 16 digits, // depending on the size. int i; for (i = 0; i < 8; i++) { int tmp = (int) (value & 0x0F); value = value >> 4; if (tmp < 10) { *local_ptr-- = '0' + tmp; } else { *local_ptr-- = 'A' + (tmp - 10); } } // Beware of right shifts that preserve the sign bit. { int tmp1 = (value & 0x0FFFF); int tmp2 = ((value >> 16) & 0x0FFFF); value = (tmp2 << 16) + tmp1; } if (value != 0) { for (i = 0; i < 8; i++) { int tmp = (int) (value & 0x0F); value = value >> 4; if (tmp < 10) { *local_ptr-- = '0' + tmp; } else { *local_ptr-- = 'A' + (tmp - 10); } } } *local_ptr-- = 'x'; *local_ptr = '0'; target = std::string(local_ptr); } else if (CdlValueFormat_Octal == format) { // Simply output the data three bits at a time, do not worry about any // particular width restrictions. However it is necessary to worry // about masking. cdl_int mask = 0x1FFFFFFF; mask = (mask << 16) | 0x0FFFF; mask = (mask << 16) | 0x0FFFF; target = ""; while (value > 0) { int tmp = value & 0x07; value = (value >> 3) & mask; *local_ptr-- = '0' + tmp; } *local_ptr = '0'; target = std::string(local_ptr); } else { // A simple decimal number // Switch to positive arithmetic. bool negative = false; if (value < 0) { negative = true; value = 0 - value; // Only MININT cannot be converted using the above line if (value < 0) { target = "-9223372036854775808"; CYG_REPORT_RETVAL(true); return; } } while (value > 0) { int rem = (int) (value % 10); value = value / 10; *local_ptr-- = '0' + rem; } if (negative) { *local_ptr-- = '-'; } local_ptr++; target = std::string(local_ptr); } CYG_REPORT_RETURN(); return; } //}}} //{{{ double_to_string() // ---------------------------------------------------------------------------- std::string Cdl::double_to_string(double value, CdlValueFormat format) { std::string result; Cdl::double_to_string(value, result, format); return result; } void Cdl::double_to_string(double value, std::string& result, CdlValueFormat format) { CYG_REPORT_FUNCNAME("Cdl::double_to_String"); char buf[256]; // This should be plenty :-) sprintf(buf, "%.*G", DBL_DIG, value); result = buf; CYG_UNUSED_PARAM(CdlValueFormat, format); CYG_REPORT_RETURN(); } //}}} //{{{ bool_to_string() // ---------------------------------------------------------------------------- // Should the string results be 1/0 or true/false? Not that // it really matters. The testcase in cdl1.cxx expects 1/0. std::string Cdl::bool_to_string(bool value) { std::string result; Cdl::bool_to_string(value, result); return result; } void Cdl::bool_to_string(bool value, std::string& target) { CYG_REPORT_FUNCNAME("Cdl::bool_to_string"); CYG_REPORT_FUNCARG1( "value arg %ld", (long) value); if (value) target = "1"; else target = "0"; CYG_REPORT_RETURN(); } //}}} //{{{ integer_to_double() // ---------------------------------------------------------------------------- // Currently integer to double cannot fail, although there may well be loss // of accurary. Eventually cdl_int may be an arbitrary precision integer // in which case conversion to double is not guaranteed. double Cdl::integer_to_double(cdl_int value) { CYG_REPORT_FUNCNAME("Cdl::integer_to_double"); double result = (double) value; CYG_REPORT_RETURN(); return result; } void Cdl::integer_to_double(cdl_int value, double& target) { CYG_REPORT_FUNCNAME("Cdl::integer_to_double"); target = (double) value; CYG_REPORT_RETURN(); } //}}} //{{{ double_to_integer() // Conversion from double to integer is only allowed if there is no loss // of data. modf() is useful here bool Cdl::double_to_integer(double value, cdl_int& target) { CYG_REPORT_FUNCNAMETYPE("Cdl::double_to_integer", "result %d"); bool result = false; double integral; double frac; frac = modf(value, &integral); if (0.0 == frac) { // Looking good, but integral may still be too big. cdl_int tmp = (cdl_int) integral; if (tmp == value) { // No fraction, no loss of data, everything looking good target = tmp; result = true; } } CYG_REPORT_RETVAL(result); return result; } //}}} //}}} //{{{ Cdl::xxx_to_yyy() - CDL-specific data types // ---------------------------------------------------------------------------- // Conversions between strings and flavors. static struct { char* name; CdlValueFlavor flavor; } valid_flavors[] = { { "none", CdlValueFlavor_None }, { "bool", CdlValueFlavor_Bool }, { "booldata", CdlValueFlavor_BoolData }, { "data", CdlValueFlavor_Data }, { 0, CdlValueFlavor_Invalid } }; bool Cdl::string_to_flavor(std::string name, CdlValueFlavor& target) { CYG_REPORT_FUNCNAMETYPE("Cdl::string_to_flavor", "success %d"); bool result = false; // First convert the argument to lower case. Arguably this is incorrect, // Tcl is a case-sensitive language, but the conversion is unlikely ever // to be harmfull. for (std::string::iterator str_i = name.begin(); str_i != name.end(); str_i++) { if (isupper(*str_i)) { *str_i = tolower(*str_i); } } // Now look for a match in the table. int match = -1; int i; const char* c_str = name.c_str(); int len = strlen(c_str); for (i = 0; 0 != valid_flavors[i].name; i++) { if (0 == strncmp(c_str, valid_flavors[i].name, len)) { // Check for an ambiguous string match. // This cannot actually happen with the current flavor names. if ( -1 != match) { break; } match = i; } } if (-1 != match) { target = valid_flavors[match].flavor; result = true; } CYG_REPORT_RETVAL(result); return result; } bool Cdl::flavor_to_string(CdlValueFlavor flavor, std::string& target) { CYG_REPORT_FUNCNAMETYPE("Cdl::flavor_to_string", "success %d"); bool result = false; for (int i = 0; 0 != valid_flavors[i].name; i++) { if (flavor == valid_flavors[i].flavor) { target = valid_flavors[i].name; result = true; break; } } CYG_REPORT_RETVAL(result); return result; } // ---------------------------------------------------------------------------- // Similar support for value sources. static struct { char* name; CdlValueSource source; } valid_sources[] = { { "default", CdlValueSource_Default }, { "inferred", CdlValueSource_Inferred }, { "wizard", CdlValueSource_Wizard }, { "user", CdlValueSource_User }, { 0, CdlValueSource_Invalid } }; bool Cdl::string_to_source(std::string name, CdlValueSource& target) { CYG_REPORT_FUNCNAMETYPE("Cdl::string_to_source", "success %d"); bool result = false; // First convert the argument to lower case. Arguably this is incorrect, // Tcl is a case-sensitive language, but the conversion is unlikely ever // to be harmfull. for (std::string::iterator str_i = name.begin(); str_i != name.end(); str_i++) { if (isupper(*str_i)) { *str_i = tolower(*str_i); } } // Now look for a match in the table. int match = -1; int i; const char* c_str = name.c_str(); int len = strlen(c_str); for (i = 0; 0 != valid_sources[i].name; i++) { if (0 == strncmp(c_str, valid_sources[i].name, len)) { // Check for an ambiguous string match. // This cannot actually happen with the current source names. if ( -1 != match) { break; } match = i; } } if (-1 != match) { target = valid_sources[match].source; result = true; } CYG_REPORT_RETVAL(result); return result; } bool Cdl::source_to_string(CdlValueSource source, std::string& target) { CYG_REPORT_FUNCNAMETYPE("Cdl::source_to_string", "success %d"); bool result = false; for (int i = 0; 0 != valid_sources[i].name; i++) { if (source == valid_sources[i].source) { target = valid_sources[i].name; result = true; break; } } CYG_REPORT_RETVAL(result); return result; } //}}} //{{{ Cdl::get_library_version() // ---------------------------------------------------------------------------- // The version of the library actually lives inside configure.in. It gets // exported into cdlconfig.h std::string Cdl::get_library_version(void) { return std::string(CYGNUM_LIBCDL_VERSION); } //}}} //{{{ Cdl::set_interactive() // ---------------------------------------------------------------------------- // Some CDL scripts and some bits of the library may want to adapt depending // on whether or not the application is running fully interactively or in // batch mode. The primary distinction is that a batch program should never // attempt to obtain user input, whether via Tk widgets or by other means. bool Cdl::interactive = false; void Cdl::set_interactive(bool value) { CYG_REPORT_FUNCNAME("Cdl::set_interactive"); CYG_REPORT_FUNCARG1D(value); interactive = value; } bool Cdl::is_interactive(void) { CYG_REPORT_FUNCNAMETYPE("Cdl::is_interactive", "interactive %d"); CYG_REPORT_RETVAL(interactive); return interactive; } //}}} //{{{ version support() // ---------------------------------------------------------------------------- // Packages may need to impose constraints on which versions of other // packages they can coexist with. This requires some way of achieving // a partial ordering of version numbers. Unfortunately there are many // different ways of specifying a version number, and we cannot impose // a single model on all third party package developers. Instead this // routine performs some semi-intelligent comparisons of two version // strings which should work in the vast majority of cases. // // The return value is as per strcmp(), -1 if the first entry is // smaller (i.e. the more recent and hence hopefully the first in // a list), +1 if the second entry is smaller, 0 if the two are // identical. // // There is a big ambiguity between "derived" versions and "experimental" // versions. Something like v0.3beta is experimental, i.e. it is older // than the full release v0.3. On the other hand v0.3.p1 is a patched // version of v0.3 and hence newer. This code uses the presence or otherwise // of a separator to decide between the two cases. // A utility routine which checks whether or not a character counts // as a separator. Currently the characters . - and _ are all accepted // as field separators. // // Arguably - should not be accepted as a separator. Instead if it preceeds // a digit it could be interpreted as part of a prerelease number. static bool is_separator(int ch) { return ('.' == ch) || ('-' == ch) || ('_' == ch); } int Cdl::compare_versions(std::string arg1, std::string arg2) { CYG_REPORT_FUNCNAMETYPE("Cdl::compare_versions", "result %d"); if (arg1 == arg2) { CYG_REPORT_RETVAL(0); return 0; } // The version number "current" is special, it always indicates the most // recent version e.g. as checked out from a CVS repository. if ("current" == arg1) { CYG_REPORT_RETVAL(-1); return -1; } if ("current" == arg2) { CYG_REPORT_RETVAL(1); return 1; } const char* ptr1 = arg1.c_str(); const char* ptr2 = arg2.c_str(); int num1 = 0; int num2 = 0; // If both strings start with 'v' or 'V', skip this. A minor variation in // case at the start of a string should be ignored. if ((('v' == *ptr1) || ('V' == *ptr1)) && (('v' == *ptr2) || ('V' == *ptr2))) { ptr1++; ptr2++; } // Now process the rest of the version string, one unit at a time. while (1) { if (('\0' == *ptr1) && ('\0' == *ptr2)) { // Both strings have terminated at the same time. There // may have been some spurious leading zeroes in numbers, // or irrelevant differences in the separators. CYG_REPORT_RETVAL(0); return 0; } if ('\0' == *ptr1) { // The first string has ended first. If the second string currently // points at a separator then arg2 is a derived version, e.g. // v0.3.p1, and hence newer. Otherwise arg2 is an experimental // version v0.3beta and hence older. if (is_separator(*ptr2)) { CYG_REPORT_RETVAL(1); return 1; } else { CYG_REPORT_RETVAL(-1); return -1; } } if ('\0' == *ptr2) { // As per the previous test. if (is_separator(*ptr1)) { CYG_REPORT_RETVAL(-1); return -1; } else { CYG_REPORT_RETVAL(1); return 1; } } // If both strings currently point at numerical data, do a conversion and // a numerical comparison. if (isdigit(*ptr1) && isdigit(*ptr2)) { num1 = 0; num2 = 0; // Strictly speaking there should be some overflow tests here, but it // is not worth the trouble. do { num1 = (10 * num1) + (*ptr1++ - '0'); } while(isdigit(*ptr1)); do { num2 = (10 * num2) + (*ptr2++ - '0'); } while(isdigit(*ptr2)); // v2.0 is newer than v1.0 if (num1 < num2) { CYG_REPORT_RETVAL(1); return 1; } else if (num1 > num2) { CYG_REPORT_RETVAL(-1); return -1; } else { continue; } } // Non-numerical data. If the two characters are the same then // move on. Note: this has to happen after numerical conversions // to distinguish v10.0 and v1.0 if (*ptr1 == *ptr2) { ptr1++; ptr2++; continue; } // If both strings are currently at a separator then move on. All // separators can be used interchangeably. if (is_separator(*ptr1) && is_separator(*ptr2)) { ptr1++; ptr2++; continue; } // If only one string is at a separator, special action // is needed. v1.1alpha is interpreted as earlier than // v1.1, but v1.1.3 is a later release. if (is_separator(*ptr1)) { return -1; } else if (is_separator(*ptr2)) { return 1; } // Two different characters, e.g. v1.0alpha vs. v1.0beta if (*ptr1 < *ptr2) { CYG_REPORT_RETVAL(1); return 1; } else { CYG_REPORT_RETVAL(-1); return -1; } } // Not reachable. } // ---------------------------------------------------------------------------- // Given a version string, extract major, minor and release numbers. // Some or all of these may be absent. Basically the code just // iterates through the string looking for sequences of numbers. static void version_extract_number(const std::string& version, unsigned int& index, std::string& result) { CYG_REPORT_FUNCNAME("version_extract_number"); // The calling code is expected to supply a sensible default. // Search for a digit for ( ; index < version.size(); index++) { if (isdigit(version[index])) { break; } } if (index != version.size()) { result = ""; if ((index > 0) && ('-' == version[index-1])) { result = "-"; } do { result += version[index++]; } while ((index < version.size()) && isdigit(version[index])); } CYG_REPORT_RETURN(); } void Cdl::split_version_string(const std::string& version, std::string& major, std::string& minor, std::string& release) { CYG_REPORT_FUNCNAME("CdlMisc::split_version_string"); unsigned int index = 0; version_extract_number(version, index, major); version_extract_number(version, index, minor); version_extract_number(version, index, release); CYG_REPORT_RETURN(); } //}}} //{{{ Cdl::get_short_form() // ---------------------------------------------------------------------------- // It is occasionally useful to take a full CDL name such as CYgpkg_KERNEL // and turn it into a short form such as "kernel". This involves discarding // everything up to and including the first underscore, then lowercasing // all subsequent characters. std::string Cdl::get_short_form(const std::string& original) { CYG_REPORT_FUNCNAME("CdlMisc::get_short_form"); std::string result = ""; unsigned int size = original.size(); unsigned int i; for (i = 0; i < size; i++) { if ('_' == original[i]) { i++; break; } } // Either at end of string, or just past the first underscore for ( ; i < size; i++) { if (isupper(original[i])) { result += tolower(original[i]); } else { result += original[i]; } } CYG_REPORT_RETURN(); return result; } //}}}
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