/********************************************************************
 * COPYRIGHT: 
 * Copyright (c) 1997-2009, International Business Machines Corporation and
 * others. All Rights Reserved.
 ********************************************************************/
/*   file name:  strtest.cpp
*   encoding:   US-ASCII
*   tab size:   8 (not used)
*   indentation:4
*
*   created on: 1999nov22
*   created by: Markus W. Scherer
*/

#include "unicode/utypes.h"
#include "unicode/putil.h"
#include "intltest.h"
#include "strtest.h"
#include "unicode/ustring.h"
#include "unicode/std_string.h"
#include "unicode/stringpiece.h"
#include <string.h>

StringTest::~StringTest() {}

void StringTest::TestEndian(void) {
    union {
        uint8_t byte;
        uint16_t word;
    } u;
    u.word=0x0100;
    if(U_IS_BIG_ENDIAN!=u.byte) {
        errln("TestEndian: U_IS_BIG_ENDIAN needs to be fixed in platform.h");
    }
}

void StringTest::TestSizeofTypes(void) {
    if(U_SIZEOF_WCHAR_T!=sizeof(wchar_t)) {
        errln("TestSizeofWCharT: U_SIZEOF_WCHAR_T!=sizeof(wchar_t) - U_SIZEOF_WCHAR_T needs to be fixed in platform.h");
    }
#ifdef U_INT64_T_UNAVAILABLE
    errln("int64_t and uint64_t are undefined.");
#else
    if(8!=sizeof(int64_t)) {
        errln("TestSizeofTypes: 8!=sizeof(int64_t) - int64_t needs to be fixed in platform.h");
    }
    if(8!=sizeof(uint64_t)) {
        errln("TestSizeofTypes: 8!=sizeof(uint64_t) - uint64_t needs to be fixed in platform.h");
    }
#endif
    if(8!=sizeof(double)) {
        errln("8!=sizeof(double) - putil.c code may not work");
    }
    if(4!=sizeof(int32_t)) {
        errln("4!=sizeof(int32_t)");
    }
    if(4!=sizeof(uint32_t)) {
        errln("4!=sizeof(uint32_t)");
    }
    if(2!=sizeof(int16_t)) {
        errln("2!=sizeof(int16_t)");
    }
    if(2!=sizeof(uint16_t)) {
        errln("2!=sizeof(uint16_t)");
    }
    if(2!=sizeof(UChar)) {
        errln("2!=sizeof(UChar)");
    }
    if(1!=sizeof(int8_t)) {
        errln("1!=sizeof(int8_t)");
    }
    if(1!=sizeof(uint8_t)) {
        errln("1!=sizeof(uint8_t)");
    }
    if(1!=sizeof(UBool)) {
        errln("1!=sizeof(UBool)");
    }
}

void StringTest::TestCharsetFamily(void) {
    unsigned char c='A';
    if( U_CHARSET_FAMILY==U_ASCII_FAMILY && c!=0x41 ||
        U_CHARSET_FAMILY==U_EBCDIC_FAMILY && c!=0xc1
    ) {
        errln("TestCharsetFamily: U_CHARSET_FAMILY needs to be fixed in platform.h");
    }
}

U_STRING_DECL(ustringVar, "aZ0 -", 5);

void StringTest::runIndexedTest(int32_t index, UBool exec, const char *&name, char * /*par*/) {
    if(exec) {
        logln("TestSuite Character and String Test: ");
    }
    switch(index) {
    case 0:
        name="TestEndian";
        if(exec) {
            TestEndian();
        }
        break;
    case 1:
        name="TestSizeofTypes";
        if(exec) {
            TestSizeofTypes();
        }
        break;
    case 2:
        name="TestCharsetFamily";
        if(exec) {
            TestCharsetFamily();
        }
        break;
    case 3:
        name="Test_U_STRING";
        if(exec) {
            U_STRING_INIT(ustringVar, "aZ0 -", 5);
            if( sizeof(ustringVar)/sizeof(*ustringVar)!=6 ||
                ustringVar[0]!=0x61 ||
                ustringVar[1]!=0x5a ||
                ustringVar[2]!=0x30 ||
                ustringVar[3]!=0x20 ||
                ustringVar[4]!=0x2d ||
                ustringVar[5]!=0
            ) {
                errln("Test_U_STRING: U_STRING_DECL with U_STRING_INIT does not work right! "
                      "See putil.h and utypes.h with platform.h.");
            }
        }
        break;
    case 4:
        name="Test_UNICODE_STRING";
        if(exec) {
            UnicodeString ustringVar=UNICODE_STRING("aZ0 -", 5);
            if( ustringVar.length()!=5 ||
                ustringVar[0]!=0x61 ||
                ustringVar[1]!=0x5a ||
                ustringVar[2]!=0x30 ||
                ustringVar[3]!=0x20 ||
                ustringVar[4]!=0x2d
            ) {
                errln("Test_UNICODE_STRING: UNICODE_STRING does not work right! "
                      "See unistr.h and utypes.h with platform.h.");
            }
        }
        break;
    case 5:
        name="Test_UNICODE_STRING_SIMPLE";
        if(exec) {
            UnicodeString ustringVar=UNICODE_STRING_SIMPLE("aZ0 -");
            if( ustringVar.length()!=5 ||
                ustringVar[0]!=0x61 ||
                ustringVar[1]!=0x5a ||
                ustringVar[2]!=0x30 ||
                ustringVar[3]!=0x20 ||
                ustringVar[4]!=0x2d
            ) {
                errln("Test_UNICODE_STRING_SIMPLE: UNICODE_STRING_SIMPLE does not work right! "
                      "See unistr.h and utypes.h with platform.h.");
            }
        }
        break;
    case 6:
        name="Test_UTF8_COUNT_TRAIL_BYTES";
        if(exec) {
            if(UTF8_COUNT_TRAIL_BYTES(0x7F) != 0
                || UTF8_COUNT_TRAIL_BYTES(0xC0) != 1
                || UTF8_COUNT_TRAIL_BYTES(0xE0) != 2
                || UTF8_COUNT_TRAIL_BYTES(0xF0) != 3)
            {
                errln("Test_UTF8_COUNT_TRAIL_BYTES: UTF8_COUNT_TRAIL_BYTES does not work right! "
                      "See utf8.h.");
            }
        }
        break;
    case 7:
        name="TestSTLCompatibility";
        if(exec) {
            TestSTLCompatibility();
        }
        break;
    case 8:
        name="TestStdNamespaceQualifier";
        if(exec) {
            TestStdNamespaceQualifier();
        }
        break;
    case 9:
        name="TestUsingStdNamespace";
        if(exec) {
            TestUsingStdNamespace();
        }
        break;
    case 10:
        name="TestStringPiece";
        if(exec) {
            TestStringPiece();
        }
        break;
    case 11:
        name="TestByteSink";
        if(exec) {
            TestByteSink();
        }
        break;
    case 12:
        name="TestCheckedArrayByteSink";
        if(exec) {
            TestCheckedArrayByteSink();
        }
        break;
    case 13:
        name="TestStringByteSink";
        if(exec) {
            TestStringByteSink();
        }
        break;
    default:
        name="";
        break;
    }
}

// Syntax check for the correct namespace qualifier for the standard string class.
void
StringTest::TestStdNamespaceQualifier() {
#if U_HAVE_STD_STRING
    U_STD_NSQ string s="abc xyz";
    U_STD_NSQ string t="abc";
    t.append(" ");
    t.append("xyz");
    if(s!=t) {
        errln("standard string concatenation error: %s != %s", s.c_str(), t.c_str());
    }
#endif
}

void
StringTest::TestUsingStdNamespace() {
#if U_HAVE_STD_STRING
    // Now test that "using namespace std;" is defined correctly.
    U_STD_NS_USE

    string s="abc xyz";
    string t="abc";
    t.append(" ");
    t.append("xyz");
    if(s!=t) {
        errln("standard string concatenation error: %s != %s", s.c_str(), t.c_str());
    }
#endif
}

void
StringTest::TestStringPiece() {
    // Default constructor.
    StringPiece empty;
    if(!empty.empty() || empty.data()!=NULL || empty.length()!=0 || empty.size()!=0) {
        errln("StringPiece() failed");
    }
    // Construct from NULL const char * pointer.
    StringPiece null(NULL);
    if(!null.empty() || null.data()!=NULL || null.length()!=0 || null.size()!=0) {
        errln("StringPiece(NULL) failed");
    }
    // Construct from const char * pointer.
    static const char *abc_chars="abc";
    StringPiece abc(abc_chars);
    if(abc.empty() || abc.data()!=abc_chars || abc.length()!=3 || abc.size()!=3) {
        errln("StringPiece(abc_chars) failed");
    }
    // Construct from const char * pointer and length.
    static const char *abcdefg_chars="abcdefg";
    StringPiece abcd(abcdefg_chars, 4);
    if(abcd.empty() || abcd.data()!=abcdefg_chars || abcd.length()!=4 || abcd.size()!=4) {
        errln("StringPiece(abcdefg_chars, 4) failed");
    }
#if U_HAVE_STD_STRING
    // Construct from std::string.
    U_STD_NSQ string uvwxyz_string("uvwxyz");
    StringPiece uvwxyz(uvwxyz_string);
    if(uvwxyz.empty() || uvwxyz.data()!=uvwxyz_string.data() || uvwxyz.length()!=6 || uvwxyz.size()!=6) {
        errln("StringPiece(uvwxyz_string) failed");
    }
#endif
    // Substring constructor with pos.
    StringPiece sp(abcd, -1);
    if(sp.empty() || sp.data()!=abcdefg_chars || sp.length()!=4 || sp.size()!=4) {
        errln("StringPiece(abcd, -1) failed");
    }
    sp=StringPiece(abcd, 5);
    if(!sp.empty() || sp.length()!=0 || sp.size()!=0) {
        errln("StringPiece(abcd, 5) failed");
    }
    sp=StringPiece(abcd, 2);
    if(sp.empty() || sp.data()!=abcdefg_chars+2 || sp.length()!=2 || sp.size()!=2) {
        errln("StringPiece(abcd, -1) failed");
    }
    // Substring constructor with pos and len.
    sp=StringPiece(abcd, -1, 8);
    if(sp.empty() || sp.data()!=abcdefg_chars || sp.length()!=4 || sp.size()!=4) {
        errln("StringPiece(abcd, -1, 8) failed");
    }
    sp=StringPiece(abcd, 5, 8);
    if(!sp.empty() || sp.length()!=0 || sp.size()!=0) {
        errln("StringPiece(abcd, 5, 8) failed");
    }
    sp=StringPiece(abcd, 2, 8);
    if(sp.empty() || sp.data()!=abcdefg_chars+2 || sp.length()!=2 || sp.size()!=2) {
        errln("StringPiece(abcd, -1) failed");
    }
    sp=StringPiece(abcd, 2, -1);
    if(!sp.empty() || sp.length()!=0 || sp.size()!=0) {
        errln("StringPiece(abcd, 5, -1) failed");
    }
    // static const npos
    const int32_t *ptr_npos=&StringPiece::npos;
    if(StringPiece::npos!=0x7fffffff || *ptr_npos!=0x7fffffff) {
        errln("StringPiece::npos!=0x7fffffff");
    }
    // substr() method with pos, using len=npos.
    sp=abcd.substr(-1);
    if(sp.empty() || sp.data()!=abcdefg_chars || sp.length()!=4 || sp.size()!=4) {
        errln("abcd.substr(-1) failed");
    }
    sp=abcd.substr(5);
    if(!sp.empty() || sp.length()!=0 || sp.size()!=0) {
        errln("abcd.substr(5) failed");
    }
    sp=abcd.substr(2);
    if(sp.empty() || sp.data()!=abcdefg_chars+2 || sp.length()!=2 || sp.size()!=2) {
        errln("abcd.substr(-1) failed");
    }
    // substr() method with pos and len.
    sp=abcd.substr(-1, 8);
    if(sp.empty() || sp.data()!=abcdefg_chars || sp.length()!=4 || sp.size()!=4) {
        errln("abcd.substr(-1, 8) failed");
    }
    sp=abcd.substr(5, 8);
    if(!sp.empty() || sp.length()!=0 || sp.size()!=0) {
        errln("abcd.substr(5, 8) failed");
    }
    sp=abcd.substr(2, 8);
    if(sp.empty() || sp.data()!=abcdefg_chars+2 || sp.length()!=2 || sp.size()!=2) {
        errln("abcd.substr(-1) failed");
    }
    sp=abcd.substr(2, -1);
    if(!sp.empty() || sp.length()!=0 || sp.size()!=0) {
        errln("abcd.substr(5, -1) failed");
    }
    // clear()
    sp=abcd;
    sp.clear();
    if(!sp.empty() || sp.data()!=NULL || sp.length()!=0 || sp.size()!=0) {
        errln("abcd.clear() failed");
    }
    // remove_prefix()
    sp=abcd;
    sp.remove_prefix(-1);
    if(sp.empty() || sp.data()!=abcdefg_chars || sp.length()!=4 || sp.size()!=4) {
        errln("abcd.remove_prefix(-1) failed");
    }
    sp=abcd;
    sp.remove_prefix(2);
    if(sp.empty() || sp.data()!=abcdefg_chars+2 || sp.length()!=2 || sp.size()!=2) {
        errln("abcd.remove_prefix(2) failed");
    }
    sp=abcd;
    sp.remove_prefix(5);
    if(!sp.empty() || sp.length()!=0 || sp.size()!=0) {
        errln("abcd.remove_prefix(5) failed");
    }
    // remove_suffix()
    sp=abcd;
    sp.remove_suffix(-1);
    if(sp.empty() || sp.data()!=abcdefg_chars || sp.length()!=4 || sp.size()!=4) {
        errln("abcd.remove_suffix(-1) failed");
    }
    sp=abcd;
    sp.remove_suffix(2);
    if(sp.empty() || sp.data()!=abcdefg_chars || sp.length()!=2 || sp.size()!=2) {
        errln("abcd.remove_suffix(2) failed");
    }
    sp=abcd;
    sp.remove_suffix(5);
    if(!sp.empty() || sp.length()!=0 || sp.size()!=0) {
        errln("abcd.remove_suffix(5) failed");
    }
}

// Verify that ByteSink is subclassable and Flush() overridable.
class SimpleByteSink : public ByteSink {
public:
    SimpleByteSink(char *outbuf) : fOutbuf(outbuf), fLength(0) {}
    virtual void Append(const char *bytes, int32_t n) {
        if(fOutbuf != bytes) {
            memcpy(fOutbuf, bytes, n);
        }
        fOutbuf += n;
        fLength += n;
    }
    virtual void Flush() { Append("z", 1); }
    int32_t length() { return fLength; }
private:
    char *fOutbuf;
    int32_t fLength;
};

// Test the ByteSink base class.
void
StringTest::TestByteSink() {
    char buffer[20];
    buffer[4] = '!';
    SimpleByteSink sink(buffer);
    sink.Append("abc", 3);
    sink.Flush();
    if(!(sink.length() == 4 && 0 == memcmp("abcz", buffer, 4) && buffer[4] == '!')) {
        errln("ByteSink (SimpleByteSink) did not Append() or Flush() as expected");
        return;
    }
    char scratch[20];
    int32_t capacity = -1;
    char *dest = sink.GetAppendBuffer(0, 50, scratch, (int32_t)sizeof(scratch), &capacity);
    if(dest != NULL || capacity != 0) {
        errln("ByteSink.GetAppendBuffer(min_capacity<1) did not properly return NULL[0]");
        return;
    }
    dest = sink.GetAppendBuffer(10, 50, scratch, 9, &capacity);
    if(dest != NULL || capacity != 0) {
        errln("ByteSink.GetAppendBuffer(scratch_capacity<min_capacity) did not properly return NULL[0]");
        return;
    }
    dest = sink.GetAppendBuffer(5, 50, scratch, (int32_t)sizeof(scratch), &capacity);
    if(dest != scratch || capacity != (int32_t)sizeof(scratch)) {
        errln("ByteSink.GetAppendBuffer() did not properly return the scratch buffer");
    }
}

void
StringTest::TestCheckedArrayByteSink() {
    char buffer[20];  // < 26 for the test code to work
    buffer[3] = '!';
    CheckedArrayByteSink sink(buffer, (int32_t)sizeof(buffer));
    sink.Append("abc", 3);
    if(!(sink.NumberOfBytesWritten() == 3 && 0 == memcmp("abc", buffer, 3) && buffer[3] == '!')) {
        errln("CheckedArrayByteSink did not Append() as expected");
        return;
    }
    char scratch[10];
    int32_t capacity = -1;
    char *dest = sink.GetAppendBuffer(0, 50, scratch, (int32_t)sizeof(scratch), &capacity);
    if(dest != NULL || capacity != 0) {
        errln("CheckedArrayByteSink.GetAppendBuffer(min_capacity<1) did not properly return NULL[0]");
        return;
    }
    dest = sink.GetAppendBuffer(10, 50, scratch, 9, &capacity);
    if(dest != NULL || capacity != 0) {
        errln("CheckedArrayByteSink.GetAppendBuffer(scratch_capacity<min_capacity) did not properly return NULL[0]");
        return;
    }
    dest = sink.GetAppendBuffer(10, 50, scratch, (int32_t)sizeof(scratch), &capacity);
    if(dest != buffer + 3 || capacity != (int32_t)sizeof(buffer) - 3) {
        errln("CheckedArrayByteSink.GetAppendBuffer() did not properly return its own buffer");
        return;
    }
    memcpy(dest, "defghijklm", 10);
    sink.Append(dest, 10);
    if(!(sink.NumberOfBytesWritten() == 13 &&
         0 == memcmp("abcdefghijklm", buffer, 13) &&
         !sink.Overflowed())
    ) {
        errln("CheckedArrayByteSink did not Append(its own buffer) as expected");
        return;
    }
    dest = sink.GetAppendBuffer(10, 50, scratch, (int32_t)sizeof(scratch), &capacity);
    if(dest != scratch || capacity != (int32_t)sizeof(scratch)) {
        errln("CheckedArrayByteSink.GetAppendBuffer() did not properly return the scratch buffer");
    }
    memcpy(dest, "nopqrstuvw", 10);
    sink.Append(dest, 10);
    if(!(sink.NumberOfBytesWritten() == (int32_t)sizeof(buffer) &&
         0 == memcmp("abcdefghijklmnopqrstuvwxyz", buffer, (int32_t)sizeof(buffer)) &&
         sink.Overflowed())
    ) {
        errln("CheckedArrayByteSink did not Append(scratch buffer) as expected");
        return;
    }
}

void
StringTest::TestStringByteSink() {
#if U_HAVE_STD_STRING
    // Not much to test because only the constructor and Append()
    // are implemented, and trivially so.
    U_STD_NSQ string result("abc");  // std::string
    StringByteSink<U_STD_NSQ string> sink(&result);
    sink.Append("def", 3);
    if(result != "abcdef") {
        errln("StringByteSink did not Append() as expected");
    }
#endif
}

#if defined(U_WINDOWS) && defined(_MSC_VER)
#include <vector>
#endif

void
StringTest::TestSTLCompatibility() {
#if defined(U_WINDOWS) && defined(_MSC_VER)
    /* Just make sure that it compiles with STL's placement new usage. */
    std::vector<UnicodeString> myvect;
    myvect.push_back(UnicodeString("blah"));
#endif
}