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|
#include "stdafx.h"
#include "ttd.h"
#include "debug.h"
#include "namegen.h"
#include "table/namegen.h"
static inline uint32 SeedChance(int shift_by, int max, uint32 seed)
{
return ((uint16)(seed >> shift_by) * max) >> 16;
}
static inline uint32 SeedModChance(int shift_by, int max, uint32 seed)
{
/* This actually gives *MUCH* more even distribution of the values
* than SeedChance(), which is absolutely horrible in that. If
* you do not believe me, try with i.e. the Czech town names,
* compare the words (nicely visible on prefixes) generated by
* SeedChance() and SeedModChance(). Do not get dicouraged by the
* never-use-modulo myths, which hold true only for the linear
* congruential generators (and Random() isn't such a generator).
* --pasky */
// TODO: Perhaps we should use it for all the name generators? --pasky
return (seed >> shift_by) % max;
}
static inline int32 SeedChanceBias(int shift_by, int max, uint32 seed, int bias)
{
return SeedChance(shift_by, max + bias, seed) - bias;
}
static void ReplaceWords(const char *org, const char *rep, char *buf)
{
if (strncmp(buf, org, 4) == 0) strncpy(buf, rep, 4);
}
static byte MakeEnglishOriginalTownName(char *buf, uint32 seed)
{
int i;
//null terminates the string for strcat
strcpy(buf, "");
// optional first segment
i = SeedChanceBias(0, lengthof(name_original_english_1), seed, 50);
if (i >= 0)
strcat(buf,name_original_english_1[i]);
//mandatory middle segments
strcat(buf, name_original_english_2[SeedChance(4, lengthof(name_original_english_2), seed)]);
strcat(buf, name_original_english_3[SeedChance(7, lengthof(name_original_english_3), seed)]);
strcat(buf, name_original_english_4[SeedChance(10, lengthof(name_original_english_4), seed)]);
strcat(buf, name_original_english_5[SeedChance(13, lengthof(name_original_english_5), seed)]);
//optional last segment
i = SeedChanceBias(15, lengthof(name_original_english_6), seed, 60);
if (i >= 0)
strcat(buf, name_original_english_6[i]);
if (buf[0] == 'C' && (buf[1] == 'e' || buf[1] == 'i'))
buf[0] = 'K';
ReplaceWords("Cunt", "East", buf);
ReplaceWords("Slag", "Pits", buf);
ReplaceWords("Slut", "Edin", buf);
//ReplaceWords("Fart", "Boot", buf);
ReplaceWords("Drar", "Quar", buf);
ReplaceWords("Dreh", "Bash", buf);
ReplaceWords("Frar", "Shor", buf);
ReplaceWords("Grar", "Aber", buf);
ReplaceWords("Brar", "Over", buf);
ReplaceWords("Wrar", "Inve", buf);
return 0;
}
static byte MakeEnglishAdditionalTownName(char *buf, uint32 seed)
{
int i;
//null terminates the string for strcat
strcpy(buf, "");
// optional first segment
i = SeedChanceBias(0, lengthof(name_additional_english_prefix), seed, 50);
if (i >= 0)
strcat(buf,name_additional_english_prefix[i]);
if (SeedChance(3, 20, seed) >= 14) {
strcat(buf, name_additional_english_1a[SeedChance(6, lengthof(name_additional_english_1a), seed)]);
} else {
strcat(buf, name_additional_english_1b1[SeedChance(6, lengthof(name_additional_english_1b1), seed)]);
strcat(buf, name_additional_english_1b2[SeedChance(9, lengthof(name_additional_english_1b2), seed)]);
if (SeedChance(11, 20, seed) >= 4) {
strcat(buf, name_additional_english_1b3a[SeedChance(12, lengthof(name_additional_english_1b3a), seed)]);
} else {
strcat(buf, name_additional_english_1b3b[SeedChance(12, lengthof(name_additional_english_1b3b), seed)]);
}
}
strcat(buf, name_additional_english_2[SeedChance(14, lengthof(name_additional_english_2), seed)]);
//optional last segment
i = SeedChanceBias(15, lengthof(name_additional_english_3), seed, 60);
if (i >= 0)
strcat(buf, name_additional_english_3[i]);
ReplaceWords("Cunt", "East", buf);
ReplaceWords("Slag", "Pits", buf);
ReplaceWords("Slut", "Edin", buf);
ReplaceWords("Fart", "Boot", buf);
ReplaceWords("Drar", "Quar", buf);
ReplaceWords("Dreh", "Bash", buf);
ReplaceWords("Frar", "Shor", buf);
ReplaceWords("Grar", "Aber", buf);
ReplaceWords("Brar", "Over", buf);
ReplaceWords("Wrar", "Stan", buf);
return 0;
}
static byte MakeAustrianTownName(char *buf, uint32 seed)
{
int i, j = 0;
strcpy(buf, "");
// Bad, Maria, Gross, ...
i = SeedChanceBias(0, lengthof(name_austrian_a1), seed, 15);
if (i >= 0) strcat(buf, name_austrian_a1[i]);
i = SeedChance(4, 6, seed);
if (i >= 4) {
// Kaisers-kirchen
strcat(buf, name_austrian_a2[SeedChance( 7, lengthof(name_austrian_a2), seed)]);
strcat(buf, name_austrian_a3[SeedChance(13, lengthof(name_austrian_a3), seed)]);
} else if (i >= 2) {
// St. Johann
strcat(buf, name_austrian_a5[SeedChance( 7, lengthof(name_austrian_a5), seed)]);
strcat(buf, name_austrian_a6[SeedChance( 9, lengthof(name_austrian_a6), seed)]);
j = 1; // More likely to have a " an der " or " am "
} else {
// Zell
strcat(buf, name_austrian_a4[SeedChance( 7, lengthof(name_austrian_a4), seed)]);
}
i = SeedChance(1, 6, seed);
if (i >= 4 - j) {
// an der Donau (rivers)
strcat(buf, name_austrian_f1[SeedChance(4, lengthof(name_austrian_f1), seed)]);
strcat(buf, name_austrian_f2[SeedChance(5, lengthof(name_austrian_f2), seed)]);
} else if (i >= 2 - j) {
// am Dachstein (mountains)
strcat(buf, name_austrian_b1[SeedChance(4, lengthof(name_austrian_b1), seed)]);
strcat(buf, name_austrian_b2[SeedChance(5, lengthof(name_austrian_b2), seed)]);
}
return 0;
}
static byte MakeGermanTownName(char *buf, uint32 seed)
{
uint i;
uint seed_derivative;
//null terminates the string for strcat
strcpy(buf, "");
seed_derivative = SeedChance(7, 28, seed);
//optional prefix
if (seed_derivative == 12 || seed_derivative == 19) {
i = SeedChance(2, lengthof(name_german_pre), seed);
strcat(buf,name_german_pre[i]);
}
// mandatory middle segments including option of hardcoded name
i = SeedChance(3, lengthof(name_german_real) + lengthof(name_german_1), seed);
if (i < lengthof(name_german_real)) {
strcat(buf,name_german_real[i]);
} else {
strcat(buf, name_german_1[i - lengthof(name_german_real)]);
i = SeedChance(5, lengthof(name_german_2), seed);
strcat(buf, name_german_2[i]);
}
// optional suffix
if (seed_derivative == 24) {
i = SeedChance(9,
lengthof(name_german_4_an_der) + lengthof(name_german_4_am), seed);
if (i < lengthof(name_german_4_an_der)) {
strcat(buf, name_german_3_an_der[0]);
strcat(buf, name_german_4_an_der[i]);
} else {
strcat(buf, name_german_3_am[0]);
strcat(buf, name_german_4_am[i - lengthof(name_german_4_an_der)]);
}
}
return 0;
}
static byte MakeSpanishTownName(char *buf, uint32 seed)
{
strcpy(buf, name_spanish_real[SeedChance(0, lengthof(name_spanish_real), seed)]);
return 0;
}
static byte MakeFrenchTownName(char *buf, uint32 seed)
{
strcpy(buf, name_french_real[SeedChance(0, lengthof(name_french_real), seed)]);
return 0;
}
static byte MakeSillyTownName(char *buf, uint32 seed)
{
strcpy(buf, name_silly_1[SeedChance( 0, lengthof(name_silly_1), seed)]);
strcat(buf, name_silly_2[SeedChance(16, lengthof(name_silly_2), seed)]);
return 0;
}
static byte MakeSwedishTownName(char *buf, uint32 seed)
{
int i;
//null terminates the string for strcat
strcpy(buf, "");
// optional first segment
i = SeedChanceBias(0, lengthof(name_swedish_1), seed, 50);
if (i >= 0)
strcat(buf, name_swedish_1[i]);
// mandatory middle segments including option of hardcoded name
if (SeedChance(4, 5, seed) >= 3) {
strcat(buf, name_swedish_2[SeedChance( 7, lengthof(name_swedish_2), seed)]);
} else {
strcat(buf, name_swedish_2a[SeedChance( 7, lengthof(name_swedish_2a), seed)]);
strcat(buf, name_swedish_2b[SeedChance(10, lengthof(name_swedish_2b), seed)]);
strcat(buf, name_swedish_2c[SeedChance(13, lengthof(name_swedish_2c), seed)]);
}
strcat(buf, name_swedish_3[SeedChance(16, lengthof(name_swedish_3), seed)]);
return 0;
}
static byte MakeDutchTownName(char *buf, uint32 seed)
{
int i;
//null terminates the string for strcat
strcpy(buf, "");
// optional first segment
i = SeedChanceBias(0, lengthof(name_dutch_1), seed, 50);
if (i >= 0)
strcat(buf, name_dutch_1[i]);
// mandatory middle segments including option of hardcoded name
if (SeedChance(6, 9, seed) > 4) {
strcat(buf, name_dutch_2[SeedChance( 9, lengthof(name_dutch_2), seed)]);
} else {
strcat(buf, name_dutch_3[SeedChance( 9, lengthof(name_dutch_3), seed)]);
strcat(buf, name_dutch_4[SeedChance(12, lengthof(name_dutch_4), seed)]);
}
strcat(buf, name_dutch_5[SeedChance(15, lengthof(name_dutch_5), seed)]);
return 0;
}
static byte MakeFinnishTownName(char *buf, uint32 seed)
{
//null terminates the string for strcat
strcpy(buf, "");
// Select randomly if town name should consists of one or two parts.
if (SeedChance(0, 15, seed) >= 10) {
strcat(buf, name_finnish_real[SeedChance( 2, lengthof(name_finnish_real), seed)]);
} else {
strcat(buf, name_finnish_1[SeedChance( 2, lengthof(name_finnish_1), seed)]);
strcat(buf, name_finnish_2[SeedChance(10, lengthof(name_finnish_2), seed)]);
}
return 0;
}
static byte MakePolishTownName(char *buf, uint32 seed)
{
uint i;
uint j;
//null terminates the string for strcat
strcpy(buf, "");
// optional first segment
i = SeedChance(0,
lengthof(name_polish_2_o) + lengthof(name_polish_2_m) +
lengthof(name_polish_2_f) + lengthof(name_polish_2_n),
seed);
j = SeedChance(2, 20, seed);
if (i < lengthof(name_polish_2_o)) {
strcat(buf, name_polish_2_o[SeedChance(3, lengthof(name_polish_2_o), seed)]);
} else if (i < lengthof(name_polish_2_m) + lengthof(name_polish_2_o)) {
if (j < 4)
strcat(buf, name_polish_1_m[SeedChance(5, lengthof(name_polish_1_m), seed)]);
strcat(buf, name_polish_2_m[SeedChance(7, lengthof(name_polish_2_m), seed)]);
if (j >= 4 && j < 16)
strcat(buf, name_polish_3_m[SeedChance(10, lengthof(name_polish_3_m), seed)]);
} else if (i < lengthof(name_polish_2_f) + lengthof(name_polish_2_m) + lengthof(name_polish_2_o)) {
if (j < 4)
strcat(buf, name_polish_1_f[SeedChance(5, lengthof(name_polish_1_f), seed)]);
strcat(buf, name_polish_2_f[SeedChance(7, lengthof(name_polish_2_f), seed)]);
if (j >= 4 && j < 16)
strcat(buf, name_polish_3_f[SeedChance(10, lengthof(name_polish_3_f), seed)]);
} else {
if (j < 4)
strcat(buf, name_polish_1_n[SeedChance(5, lengthof(name_polish_1_n), seed)]);
strcat(buf, name_polish_2_n[SeedChance(7, lengthof(name_polish_2_n), seed)]);
if (j >= 4 && j < 16)
strcat(buf, name_polish_3_n[SeedChance(10, lengthof(name_polish_3_n), seed)]);
}
return 0;
}
static byte MakeCzechTownName(char *buf, uint32 seed)
{
/* Probability of prefixes/suffixes */
/* 0..11 prefix, 12..13 prefix+suffix, 14..17 suffix, 18..31 nothing */
int prob_tails;
bool do_prefix, do_suffix, dynamic_subst;
/* IDs of the respective parts */
int prefix = 0, stem = 0, postfix = 0, ending = 0, suffix = 0;
/* The select criteria. */
enum CzechGender gender;
enum CzechChoose choose;
enum CzechAllow allow;
// 1:3 chance to use a real name.
if (SeedModChance(0, 4, seed) == 0) {
strcpy(buf, name_czech_real[SeedModChance(4, lengthof(name_czech_real), seed)]);
return 0;
}
// NUL terminates the string for strcat()
strcpy(buf, "");
prob_tails = SeedModChance(2, 32, seed);
do_prefix = prob_tails < 12;
do_suffix = prob_tails > 11 && prob_tails < 17;
if (do_prefix) prefix = SeedModChance(5, lengthof(name_czech_adj) * 12, seed) / 12;
if (do_suffix) suffix = SeedModChance(7, lengthof(name_czech_suffix), seed);
// 3:1 chance 3:1 to use dynamic substantive
stem = SeedModChance(9, lengthof(name_czech_subst_full)
+ 3 * lengthof(name_czech_subst_stem),
seed);
if (stem < (int) lengthof(name_czech_subst_full)) {
// That was easy!
dynamic_subst = false;
gender = name_czech_subst_full[stem].gender;
choose = name_czech_subst_full[stem].choose;
allow = name_czech_subst_full[stem].allow;
} else {
unsigned int map[lengthof(name_czech_subst_ending)];
int ending_start = -1, ending_stop = -1;
int i;
// Load the substantive
dynamic_subst = true;
stem -= lengthof(name_czech_subst_full);
stem %= lengthof(name_czech_subst_stem);
gender = name_czech_subst_stem[stem].gender;
choose = name_czech_subst_stem[stem].choose;
allow = name_czech_subst_stem[stem].allow;
// Load the postfix (1:1 chance that a postfix will be inserted)
postfix = SeedModChance(14, lengthof(name_czech_subst_postfix) * 2, seed);
if (choose & CZC_POSTFIX) {
// Always get a real postfix.
postfix %= lengthof(name_czech_subst_postfix);
}
if (choose & CZC_NOPOSTFIX) {
// Always drop a postfix.
postfix += lengthof(name_czech_subst_postfix);
}
if (postfix < (int) lengthof(name_czech_subst_postfix))
choose |= CZC_POSTFIX;
else
choose |= CZC_NOPOSTFIX;
// Localize the array segment containing a good gender
for (ending = 0; ending < (int) lengthof(name_czech_subst_ending); ending++) {
const struct CzechNameSubst *e = &name_czech_subst_ending[ending];
if (gender == CZG_FREE
|| (gender == CZG_NFREE && e->gender != CZG_SNEUT && e->gender != CZG_PNEUT)
|| (gender == e->gender)) {
if (ending_start < 0)
ending_start = ending;
} else if (ending_start >= 0) {
ending_stop = ending - 1;
break;
}
}
if (ending_stop < 0) {
// Whoa. All the endings matched.
ending_stop = ending - 1;
}
// Make a sequential map of the items with good mask
i = 0;
for (ending = ending_start; ending <= ending_stop; ending++) {
const struct CzechNameSubst *e = &name_czech_subst_ending[ending];
if ((e->choose & choose) == choose && (e->allow & allow) != 0)
map[i++] = ending;
}
assert(i > 0);
// Load the ending
ending = map[SeedModChance(16, i, seed)];
// Override possible CZG_*FREE; this must be a real gender,
// otherwise we get overflow when modifying the adjectivum.
gender = name_czech_subst_ending[ending].gender;
assert(gender != CZG_FREE && gender != CZG_NFREE);
}
if (do_prefix && (name_czech_adj[prefix].choose & choose) != choose) {
// Throw away non-matching prefix.
do_prefix = false;
}
// Now finally construct the name
if (do_prefix) {
enum CzechPattern pattern = name_czech_adj[prefix].pattern;
int endpos;
strcat(buf, name_czech_adj[prefix].name);
endpos = strlen(buf) - 1;
if (gender == CZG_SMASC && pattern == CZP_PRIVL) {
/* -ovX -> -uv */
buf[endpos - 2] = 'u';
assert(buf[endpos - 1] == 'v');
buf[endpos] = '\0';
} else {
buf[endpos] = name_czech_patmod[gender][pattern];
}
strcat(buf, " ");
}
if (dynamic_subst) {
strcat(buf, name_czech_subst_stem[stem].name);
if (postfix < (int) lengthof(name_czech_subst_postfix)) {
const char *poststr = name_czech_subst_postfix[postfix];
const char *endstr = name_czech_subst_ending[ending].name;
int postlen, endlen;
postlen = strlen(poststr);
endlen = strlen(endstr);
assert(postlen > 0 && endlen > 0);
// Kill the "avava" and "Jananna"-like cases
if (postlen < 2 || postlen > endlen
|| ((poststr[1] != 'v' || poststr[1] != endstr[1])
&& poststr[2] != endstr[1])) {
int buflen;
strcat(buf, poststr);
buflen = strlen(buf);
// k-i -> c-i, h-i -> z-i
if (endstr[0] == 'i') {
if (buf[buflen - 1] == 'k')
buf[buflen - 1] = 'c';
else if (buf[buflen - 1] == 'h')
buf[buflen - 1] = 'z';
}
}
}
strcat(buf, name_czech_subst_ending[ending].name);
} else {
strcat(buf, name_czech_subst_full[stem].name);
}
if (do_suffix) {
strcat(buf, " ");
strcat(buf, name_czech_suffix[suffix]);
}
return 0;
}
static byte MakeRomanianTownName(char *buf, uint32 seed)
{
strcpy(buf, name_romanian_real[SeedChance(0, lengthof(name_romanian_real), seed)]);
return 0;
}
static byte MakeSlovakTownName(char *buf, uint32 seed)
{
strcpy(buf, name_slovak_real[SeedChance(0, lengthof(name_slovak_real), seed)]);
return 0;
}
static byte MakeNorwegianTownName(char *buf, uint32 seed)
{
strcpy(buf, "");
// Use first 4 bit from seed to decide whether or not this town should
// have a real name 3/16 chance. Bit 0-3
if (SeedChance(0, 15, seed) < 3) {
// Use 7bit for the realname table index. Bit 4-10
strcat(buf, name_norwegian_real[SeedChance(4, lengthof(name_norwegian_real), seed)]);
} else {
// Use 7bit for the first fake part. Bit 4-10
strcat(buf, name_norwegian_1[SeedChance(4, lengthof(name_norwegian_1), seed)]);
// Use 7bit for the last fake part. Bit 11-17
strcat(buf, name_norwegian_2[SeedChance(11, lengthof(name_norwegian_2), seed)]);
}
return 0;
}
static byte MakeHungarianTownName(char *buf, uint32 seed)
{
uint i;
//null terminates the string for strcat
strcpy(buf, "");
if (SeedChance(12, 15, seed) < 3) {
strcat(buf, name_hungarian_real[SeedChance(0, lengthof(name_hungarian_real), seed)]);
} else {
// optional first segment
i = SeedChance(3, lengthof(name_hungarian_1) * 3, seed);
if (i < lengthof(name_hungarian_1))
strcat(buf, name_hungarian_1[i]);
// mandatory middle segments
strcat(buf, name_hungarian_2[SeedChance(3, lengthof(name_hungarian_2), seed)]);
strcat(buf, name_hungarian_3[SeedChance(6, lengthof(name_hungarian_3), seed)]);
// optional last segment
i = SeedChance(10, lengthof(name_hungarian_4) * 3, seed);
if (i < lengthof(name_hungarian_4)) {
strcat(buf, name_hungarian_4[i]);
}
}
return 0;
}
static byte MakeSwissTownName(char *buf, uint32 seed)
{
strcpy(buf, name_swiss_real[SeedChance(0, lengthof(name_swiss_real), seed)]);
return 0;
}
TownNameGenerator * const _town_name_generators[] =
{
MakeEnglishOriginalTownName,
MakeFrenchTownName,
MakeGermanTownName,
MakeEnglishAdditionalTownName,
MakeSpanishTownName,
MakeSillyTownName,
MakeSwedishTownName,
MakeDutchTownName,
MakeFinnishTownName,
MakePolishTownName,
MakeSlovakTownName,
MakeNorwegianTownName,
MakeHungarianTownName,
MakeAustrianTownName,
MakeRomanianTownName,
MakeCzechTownName,
MakeSwissTownName,
};
// DO WE NEED THIS ANY MORE?
#define FIXNUM(x, y, z) (((((x) << 16) / (y)) + 1) << z)
uint32 GetOldTownName(uint32 townnameparts, byte old_town_name_type)
{
switch (old_town_name_type) {
case 0: case 3: /* English, American */
/* Already OK */
return townnameparts;
case 1: /* French */
/* For some reason 86 needs to be subtracted from townnameparts
* 0000 0000 0000 0000 0000 0000 1111 1111 */
return FIXNUM(townnameparts - 86, lengthof(name_french_real), 0);
case 2: /* German */
DEBUG(misc, 0) ("German Townnames are buggy... (%d)", townnameparts);
return townnameparts;
case 4: /* Latin-American */
/* 0000 0000 0000 0000 0000 0000 1111 1111 */
return FIXNUM(townnameparts, lengthof(name_spanish_real), 0);
case 5: /* Silly */
/* NUM_SILLY_1 - lower 16 bits
* NUM_SILLY_2 - upper 16 bits without leading 1 (first 8 bytes)
* 1000 0000 2222 2222 0000 0000 1111 1111 */
return FIXNUM(townnameparts, lengthof(name_silly_1), 0) | FIXNUM(((townnameparts >> 16)&0xFF), lengthof(name_silly_2), 16);
}
return 0;
}
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