static void _test_set_several_whole_blocks(void *fixture)
{
_set_cycle(fixture, byte(5, 0), byte(10, 0));
}
static void four_rounds(pelican_state *pelmac)
{
ulong32 s0, s1, s2, s3, t0, t1, t2, t3;
int r;
LOAD32H(s0, pelmac->state );
LOAD32H(s1, pelmac->state + 4);
LOAD32H(s2, pelmac->state + 8);
LOAD32H(s3, pelmac->state + 12);
for (r = 0; r < 4; r++) {
t0 =
Te0(byte(s0, 3)) ^
Te1(byte(s1, 2)) ^
Te2(byte(s2, 1)) ^
Te3(byte(s3, 0));
t1 =
Te0(byte(s1, 3)) ^
Te1(byte(s2, 2)) ^
Te2(byte(s3, 1)) ^
Te3(byte(s0, 0));
t2 =
Te0(byte(s2, 3)) ^
Te1(byte(s3, 2)) ^
Te2(byte(s0, 1)) ^
Te3(byte(s1, 0));
t3 =
Te0(byte(s3, 3)) ^
Te1(byte(s0, 2)) ^
Te2(byte(s1, 1)) ^
Te3(byte(s2, 0));
s0 = t0; s1 = t1; s2 = t2; s3 = t3;
}
STORE32H(s0, pelmac->state );
STORE32H(s1, pelmac->state + 4);
STORE32H(s2, pelmac->state + 8);
STORE32H(s3, pelmac->state + 12);
}
/**
Initialize the AES (Rijndael) block cipher
@param key The symmetric key you wish to pass
@param keylen The key length in bytes
@param num_rounds The number of rounds desired (0 for default)
@param skey The key in as scheduled by this function.
@return CRYPT_OK if successful
*/
int SETUP(const unsigned char *key, int keylen, int num_rounds, symmetric_key *skey)
{
int i, j;
ulong32 temp, *rk;
#ifndef ENCRYPT_ONLY
ulong32 *rrk;
#endif
LTC_ARGCHK(key != NULL);
LTC_ARGCHK(skey != NULL);
if (keylen != 16 && keylen != 24 && keylen != 32) {
return CRYPT_INVALID_KEYSIZE;
}
if (num_rounds != 0 && num_rounds != (10 + ((keylen/8)-2)*2)) {
return CRYPT_INVALID_ROUNDS;
}
skey->rijndael.Nr = 10 + ((keylen/8)-2)*2;
/* setup the forward key */
i = 0;
rk = skey->rijndael.eK;
LOAD32H(rk[0], key );
LOAD32H(rk[1], key + 4);
LOAD32H(rk[2], key + 8);
LOAD32H(rk[3], key + 12);
if (keylen == 16) {
j = 44;
for (;;) {
temp = rk[3];
rk[4] = rk[0] ^ setup_mix(temp) ^ rcon[i];
rk[5] = rk[1] ^ rk[4];
rk[6] = rk[2] ^ rk[5];
rk[7] = rk[3] ^ rk[6];
if (++i == 10) {
break;
}
rk += 4;
}
} else if (keylen == 24) {
j = 52;
LOAD32H(rk[4], key + 16);
LOAD32H(rk[5], key + 20);
for (;;) {
#ifdef _MSC_VER
temp = skey->rijndael.eK[rk - skey->rijndael.eK + 5];
#else
temp = rk[5];
#endif
rk[ 6] = rk[ 0] ^ setup_mix(temp) ^ rcon[i];
rk[ 7] = rk[ 1] ^ rk[ 6];
rk[ 8] = rk[ 2] ^ rk[ 7];
rk[ 9] = rk[ 3] ^ rk[ 8];
if (++i == 8) {
break;
}
rk[10] = rk[ 4] ^ rk[ 9];
rk[11] = rk[ 5] ^ rk[10];
rk += 6;
}
} else if (keylen == 32) {
j = 60;
LOAD32H(rk[4], key + 16);
LOAD32H(rk[5], key + 20);
LOAD32H(rk[6], key + 24);
LOAD32H(rk[7], key + 28);
for (;;) {
#ifdef _MSC_VER
temp = skey->rijndael.eK[rk - skey->rijndael.eK + 7];
#else
temp = rk[7];
#endif
rk[ 8] = rk[ 0] ^ setup_mix(temp) ^ rcon[i];
rk[ 9] = rk[ 1] ^ rk[ 8];
rk[10] = rk[ 2] ^ rk[ 9];
rk[11] = rk[ 3] ^ rk[10];
if (++i == 7) {
break;
}
temp = rk[11];
rk[12] = rk[ 4] ^ setup_mix(RORc(temp, 8));
rk[13] = rk[ 5] ^ rk[12];
rk[14] = rk[ 6] ^ rk[13];
rk[15] = rk[ 7] ^ rk[14];
rk += 8;
}
} else {
/* this can't happen */
return CRYPT_ERROR;
}
#ifndef ENCRYPT_ONLY
/* setup the inverse key now */
rk = skey->rijndael.dK;
rrk = skey->rijndael.eK + j - 4;
/* apply the inverse MixColumn transform to all round keys but the first and the last: */
/* copy first */
*rk++ = *rrk++;
*rk++ = *rrk++;
*rk++ = *rrk++;
*rk = *rrk;
rk -= 3; rrk -= 3;
for (i = 1; i < skey->rijndael.Nr; i++) {
rrk -= 4;
rk += 4;
#ifdef LTC_SMALL_CODE
temp = rrk[0];
rk[0] = setup_mix2(temp);
temp = rrk[1];
rk[1] = setup_mix2(temp);
temp = rrk[2];
rk[2] = setup_mix2(temp);
temp = rrk[3];
rk[3] = setup_mix2(temp);
#else
temp = rrk[0];
rk[0] =
Tks0[byte(temp, 3)] ^
Tks1[byte(temp, 2)] ^
Tks2[byte(temp, 1)] ^
Tks3[byte(temp, 0)];
temp = rrk[1];
rk[1] =
Tks0[byte(temp, 3)] ^
Tks1[byte(temp, 2)] ^
Tks2[byte(temp, 1)] ^
Tks3[byte(temp, 0)];
temp = rrk[2];
rk[2] =
Tks0[byte(temp, 3)] ^
Tks1[byte(temp, 2)] ^
Tks2[byte(temp, 1)] ^
Tks3[byte(temp, 0)];
temp = rrk[3];
rk[3] =
Tks0[byte(temp, 3)] ^
Tks1[byte(temp, 2)] ^
Tks2[byte(temp, 1)] ^
Tks3[byte(temp, 0)];
#endif
}
/* copy last */
rrk -= 4;
rk += 4;
*rk++ = *rrk++;
*rk++ = *rrk++;
*rk++ = *rrk++;
*rk = *rrk;
#endif /* ENCRYPT_ONLY */
return CRYPT_OK;
}
void
CBulletVolume::render( centity_t& ent )
{
entityState_t& es = ent.currentState;
if (!(es.groundEntityNum & BVF_ENABLED))
return;
// Setup refent.
refEntity_t re;
memset( &re, 0, sizeof(re) );
re.reType = RT_MODEL;
re.renderfx = RF_NOSHADOW;
re.hModel = cgs.media.polygonCubeFO;
re.nonNormalizedAxes = qtrue;
re.customShader = cgs.media.bulletVolumeShader;
re.shaderRGBA[3] = byte(es.angles2[2] * 255.0f);
switch (es.modelindex) {
default: // UNKNWON -> GRAY
case 0:
re.shaderRGBA[0] = byte(0.5f * 255.0f);
re.shaderRGBA[1] = byte(0.5f * 255.0f);
re.shaderRGBA[2] = byte(0.5f * 255.0f);
break;
case 1: // NOHIT -> BLUE
re.shaderRGBA[0] = byte(0.0f * 255.0f);
re.shaderRGBA[1] = byte(0.0f * 255.0f);
re.shaderRGBA[2] = byte(1.0f * 255.0f);
break;
case 2: // HIT -> RED
re.shaderRGBA[0] = byte(1.0f * 255.0f);
re.shaderRGBA[1] = byte(0.0f * 255.0f);
re.shaderRGBA[2] = byte(0.0f * 255.0f);
break;
case 3: // REFERENCE NOHIT -> GREEN
re.shaderRGBA[0] = byte(0.0f * 255.0f);
re.shaderRGBA[1] = byte(1.0f * 255.0f);
re.shaderRGBA[2] = byte(0.0f * 255.0f);
break;
case 4: // REFERENCE HIT -> YELLOW
re.shaderRGBA[0] = byte(1.0f * 255.0f);
re.shaderRGBA[1] = byte(1.0f * 255.0f);
re.shaderRGBA[2] = byte(0.0f * 255.0f);
break;
}
// Apply entity rotation.
AxisClear( re.axis );
AnglesToAxis( es.angles, re.axis );
// Apply scaling matrix.
vec3_t smatrix[3];
AxisClear( smatrix );
smatrix[0][0] *= es.origin2[0];
smatrix[1][1] *= es.origin2[1];
smatrix[2][2] *= es.origin2[2];
vec3_t tmp[3];
MatrixMultiply( smatrix, re.axis, tmp );
AxisCopy( tmp, re.axis );
// Set origins.
VectorCopy( es.origin, re.origin );
VectorCopy( es.origin, re.oldorigin );
VectorCopy( es.origin, re.lightingOrigin );
trap_R_AddRefEntityToScene( &re );
}
int onebyteinstr()
{
int r, b, x, y, y1, y2;
b=PeekOneByte();
//fprintf(stderr, "b=%02X",b),getch();
switch(opcodeTable[b])
{
case 0: r=op(); if(!r) return 0; x=result;
//fprintf(stderr, "x=%02X",x),getch();
i_opclass=0; i_opcode=x;
break;
case 1: r=op(); if(!r) return 0; x=result;
r=byte(); if(!r) return 0; y=result;
i_opclass=1; i_opcode=x; i_byte=y;
break;
case 2: r=op(); if(!r) return 0; x=result;
r=word(); if(!r) return 0; y=result;
i_opclass=2; i_opcode=x; i_word=y;
break;
case 3: r=op(); if(!r) return 0; x=result;
r=word(); if(!r) return 0; y1=result;
r=byte(); if(!r) return 0; y2=result;
i_opclass=3; i_opcode=x; i_word=y1; i_byte=y2;
break;
case 4: r=op(); if(!r) return 0; x=result;
r=wdword(); if(!r) return 0; y=result;
i_opclass=4; i_opcode=x; i_dword=y;
break;
case 44: r=op(); if(!r) return 0; x=result;
r=adword(); if(!r) return 0; y=result;
i_opclass=4; i_opcode=x; i_dword=y;
break;
case 5: r=op(); if(!r) return 0; x=result;
r=pword(); if(!r) return 0;
i_opclass=5; i_opcode=x;
break;
case 6: r=op(); if(!r) return 0; x=result;
r=modrm(); if(!r) return 0;
i_opclass=6; i_opcode=x;
break;
case 7: r=op(); if(!r) return 0; x=result;
r=modrm(); if(!r) return 0;
r=byte(); if(!r) return 0; y=result;
i_opclass=7; i_opcode=x; i_byte=y;
break;
case 8: r=op(); if(!r) return 0; x=result;
r=modrm(); if(!r) return 0;
r=wdword(); if(!r) return 0; y=result;
i_opclass=8; i_opcode=x; i_dword=y;
break;
case 9: r=op(); if(!r) return 0; x=result;
r=opext(); if(!r) return 0;
i_opclass=9; i_opcode=x;
break;
case 10: r=op(); if(!r) return 0; x=result;
r=opext(); if(!r) return 0;
r=byte(); if(!r) return 0; y=result;
i_opclass=10; i_opcode=x; i_byte=y;
break;
case 11: r=op(); if(!r) return 0; x=result;
r=opext(); if(!r) return 0;
r=wdword(); if(!r) return 0; y=result;
i_opclass=11; i_opcode=x; i_dword=y;
break;
case 12: r=op(); if(!r) return 0; x=result;
r=opextg(); if(!r) return 0;
i_opclass=12; i_opcode=x;
break;
case 13: r=op(); if(!r) return 0; x=result; // case jump block
b=PeekOneByte();
if (b==36)
{
b=PeekSecondByte();
if (rmTable[b]==5)
{
r=op(); if(!r) return 0; y1=result;
r=op(); if(!r) return 0; y2=result;
i_opclass=13;
i_opcode=x;
i_mod=y1;
i_sib=y2;
r=labelstartposition(); if(!r) return 0;
// ..................................................................
if (nextMode)
{
r=label1();
finished=1;
if(!r) return 1; // need to be careful ...
}
return 1;
}
}
//else
{
b=PeekOneByte();
if (regTable[b]<7)
{
r=opext(); if(!r) return 0;
i_opclass=13; i_opcode=x;
}
else return 0;
}
break;
case 14: r=op(); if(!r) return 0; x=result; // test group
if (x==246)
{
b=PeekOneByte();
if (regTable[b]==0)
{
r=opext(); if(!r) return 0;
r=byte(); if(!r) return 0; y=result;
i_opclass=14; i_opcode=x; i_byte=y;
}
else if (regTable[b]>1)
{
r=opext(); if(!r) return 0;
i_opclass=14; i_opcode=x;
}
else return 0;
}
else
{
b=PeekOneByte();
if (regTable[b]==0)
{
r=opext(); if(!r) return 0;
r=wdword(); if(!r) return 0; y=result;
i_opclass=14; i_opcode=x; i_dword=y;
}
else
{
r=opext(); if(!r) return 0;
i_opclass=14; i_opcode=x;
}
}
break;
case 15: r=op(); if(!r) return 0; x=result; // wait group
i_opclass=15; i_opcode=x;
b=PeekOneByte();
if (b==217)
{
b=PeekSecondByte();
if (regTable[b]==6||regTable[b]==7)
{
r=op(); if(!r) return 0; y=result;
r=opext(); if(!r) return 0;
i_opcode=y; prefixStack[i_psp++]=x;
}
}
else if (b==219)
{
b=PeekSecondByte();
if (b==226||b==227)
{
r=op(); if(!r) return 0; y1=result;
r=op(); if(!r) return 0; y2=result;
i_opcode=y1; i_mod=y2; prefixStack[i_psp++]=x;
}
}
else if (b==221)
{
b=PeekSecondByte();
if (regTable[b]==6||regTable[b]==7)
{
r=op(); if(!r) return 0; y=result;
r=opext(); if(!r) return 0;
i_opcode=y; prefixStack[i_psp++]=x;
}
}
else if (b==223)
{
b=PeekSecondByte();
if (b==224)
{
r=op(); if(!r) return 0; y1=result;
r=op(); if(!r) return 0; y2=result;
i_opcode=y1; i_mod=y2; prefixStack[i_psp++]=x;
}
}
break;
case 16: r=op(); if(!r) return 0; x=result; // repeat group
if (x==242)
{
while(prefixes());
b=PeekOneByte();
if (repeatgroupTable[b]==1)
{
r=op(); if(!r) return 0; y=result;
i_opclass=16; i_opcode=y; prefixStack[i_psp++]=x;
}
else return 0;
}
else
{
while(prefixes());
b=PeekOneByte();
if (repeatgroupTable[b]>0)
{
r=op(); if(!r) return 0; y=result;
i_opclass=16; i_opcode=y; prefixStack[i_psp++]=x;
}
else return 0;
}
break;
default: return 0;
}
return 1;
}
void Lamp::drawCycle()
{
long hTime;
long fTime;
switch (getDisplayMode())
{
case lCYCLE:
hTime = getCycleHoldTime();
fTime = getCycleFadeTime();
break;
case lRANDOM:
hTime = getRandomHoldTime();
fTime = getRandomFadeTime();
break;
default:
break;
}
long totalCycleLen = (hTime + fTime)*1000;
totalCycleLen &=0x0000FFFF;
long _step = millis() % totalCycleLen;
//end of cycle;
if (_step >= hTime*1000 && _step <=(hTime*1000)+10 && _stepped==false)
{
_stepped = true;
switch (getDisplayMode())
{
case lCYCLE:
_targetHue += getCycleSteps();
break;
case lRANDOM:
_targetHue += random(-getCycleSteps()*2,getCycleSteps()*2);
break;
default:
break;
}
// Serial.println(_targetHue);
_fadeDirection =0;
_fadeSteps = 0;
unsigned char _tmp = 0;
unsigned char _a = _currentHue;
while (_a != _targetHue)
{
_a++;
_tmp++;
}
_fadeSteps = _tmp;
_fadeDirection = 1;
_tmp = 0;
_a = _currentHue;
while (_a != _targetHue)
{
_a--;
_tmp++;
}
if (_tmp < _fadeSteps)
{
_fadeSteps = _tmp;
_fadeDirection = -1;
}
}
//fade
else if (_step >= (hTime*1000)+15)
{
_stepped=false;
if (_currentHue != _targetHue)
{
long incStep =(fTime*1000)/_fadeSteps ;
if (_step % incStep < _prevSubStep) _currentHue+= _fadeDirection;
_prevSubStep = _step % incStep;
}
}
_ledColors[0] = hsbToRGB(getColorHue() +_currentHue,getColorSat(),ambBrightness);
_ledColors[1] = hsbToRGB(byte(getColorHue() +_currentHue - (getCycleSteps()*(PI/1.5f) )),byte(getColorSat()/1.2f),ambBrightness);
_prevStep = _step;
}
//===========================================================================
// DS_Load
//===========================================================================
void DS_Load(sfxbuffer_t *buf, struct sfxsample_s *sample)
{
#define SAMPLE_SILENCE 16 // Samples to interpolate to silence.
#define SAMPLE_ROUNDOFF 32 // The length is a multiple of this.
LPDIRECTSOUNDBUFFER newSound = NULL;
LPDIRECTSOUND3DBUFFER newSound3D = NULL;
bool play3d = !!(buf->flags & SFXBF_3D);
void *writePtr1 = NULL, *writePtr2 = NULL;
DWORD writeBytes1, writeBytes2;
unsigned int safeNumSamples = sample->numsamples + SAMPLE_SILENCE;
unsigned int safeSize, i;
int last, delta;
// Does the buffer already have a sample loaded?
if(buf->sample)
{
// Is the same one?
if(buf->sample->id == sample->id) return;
}
// The safe number of samples is rounded to the next highest
// count of SAMPLE_ROUNDOFF.
if((i = safeNumSamples % SAMPLE_ROUNDOFF) != 0)
{
safeNumSamples += SAMPLE_ROUNDOFF - i;
/*#if _DEBUG
Con_Message("Safelen = %i\n", safeNumSamples);
#endif*/
}
safeSize = safeNumSamples * sample->bytesper;
/*#if _DEBUG
Con_Message("Safesize = %i\n", safeSize);
#endif*/
// If a sample has already been loaded, unload it.
FreeDSBuffers(buf);
// Create the DirectSound buffer. Its length will match the sample
// exactly.
if(FAILED(hr = CreateDSBuffer(DSBCAPS_CTRLVOLUME | DSBCAPS_CTRLFREQUENCY
| DSBCAPS_STATIC | (play3d? DSBCAPS_CTRL3D
| DSBCAPS_MUTE3DATMAXDISTANCE : DSBCAPS_CTRLPAN),
safeNumSamples, buf->freq, buf->bytes*8, 1, &newSound)))
{
if(verbose) Error("DS_Load", "Couldn't create a new buffer.");
return;
}
if(play3d)
{
// Query the 3D interface.
if(FAILED(hr = newSound->QueryInterface(IID_IDirectSound3DBuffer,
(void**) &newSound3D)))
{
if(verbose) Error("DS_Load", "Couldn't get 3D buffer interface.");
newSound->Release();
return;
}
}
// Lock and load!
newSound->Lock(0, 0, &writePtr1, &writeBytes1,
&writePtr2, &writeBytes2, DSBLOCK_ENTIREBUFFER);
if(writePtr2 && verbose) Error("DS_Load", "Unexpected buffer lock behavior.");
// Copy the sample data.
memcpy(writePtr1, sample->data, sample->size);
/*Con_Message("Fill %i bytes (orig=%i).\n", safeSize - sample->size,
sample->size);*/
// Interpolate to silence.
// numSafeSamples includes at least SAMPLE_ROUNDOFF extra samples.
last = sample->bytesper==1? ((byte*)sample->data)[sample->numsamples - 1]
: ((short*)sample->data)[sample->numsamples - 1];
delta = sample->bytesper==1? 0x80 - last : -last;
//Con_Message("last = %i\n", last);
for(i = 0; i < safeNumSamples - sample->numsamples; i++)
{
float pos = i/(float)SAMPLE_SILENCE;
if(pos > 1) pos = 1;
if(sample->bytesper == 1) // 8-bit sample.
{
((byte*)writePtr1)[sample->numsamples + i] =
byte( last + delta*pos );
}
else // 16-bit sample.
{
((short*)writePtr1)[sample->numsamples + i] =
short( last + delta*pos );
}
}
// Unlock the buffer.
newSound->Unlock(writePtr1, writeBytes1, writePtr2, writeBytes2);
buf->ptr = newSound;
buf->ptr3d = newSound3D;
buf->sample = sample;
}
void LEDS::fade()
{
int colorScenario;
setBlueRedGreenComp(Color1);
colorScenario = findColorCase();
adjustFadeDelta();
switch (colorScenario)
{
case 1:
greenComp = greenComp + fadeDelta;
break;
case 2:
redComp = redComp + fadeDelta;
break;
case 3:
if(greenComp +fadeDelta*(greenComp/redComp) < 0)
{
fadeDelta = FADINGDELTA;
}
if(greenComp +fadeDelta*(greenComp/redComp) > 31)
{
fadeDelta = -FADINGDELTA;
}
greenComp = byte(greenComp + fadeDelta*(greenComp/redComp));
redComp = redComp + fadeDelta;
break;
case 4:
blueComp = blueComp + fadeDelta;
break;
case 5:
if(greenComp +fadeDelta*(greenComp/blueComp) < 0)
{
fadeDelta = FADINGDELTA;
}
if(greenComp +fadeDelta*(greenComp/blueComp) > 31)
{
fadeDelta = -FADINGDELTA;
}
greenComp = byte(greenComp + fadeDelta*(greenComp/blueComp));
blueComp = blueComp + fadeDelta;
break;
case 6:
if(redComp +fadeDelta*(redComp/blueComp) < 0)
{
fadeDelta = FADINGDELTA;
}
if(redComp +fadeDelta*(redComp/blueComp) > 31)
{
fadeDelta = -FADINGDELTA;
}
redComp = byte(redComp + fadeDelta*(redComp/blueComp));
blueComp = blueComp + fadeDelta;
break;
case 7:
redComp = byte(redComp + fadeDelta*(redComp/blueComp));
greenComp = byte(greenComp + fadeDelta*(greenComp/blueComp));
blueComp = blueComp + fadeDelta;
break;
default:
break;
}
Color1 = Color(blueComp, redComp, greenComp);
setOneColorForAll(Color1);
}
byte LEDS::getBlueComp(uint16_t Color)
{
return byte(Color & 0x1F);
}
static byte current_to_wiper(float current) {
return byte(ceil(float((DIGIPOT_I2C_FACTOR * current))));
}
void EXROMClass::write(int writePointer, char writeDataStore) //write a char to EEPROM
{
write(writePointer, byte(writeDataStore));
}
static void _test_set_many_boundaries(void *fixture)
{
_set_cycle(fixture, byte(13, 13), byte(23, 13));
}
static void _test_set_cross_one_boundary(void *fixture)
{
_set_cycle(fixture, byte(13, 43), byte(14, 43));
}
static void _test_set_within_single_block(void *fixture)
{
_set_cycle(fixture, byte(7, 3), byte(7, T_BLOCK_SIZE / 2));
}
long Lamp::hsbToRGB(unsigned char h, unsigned char s, unsigned char b)
{
float fH = (float(h) /255.00f)*360.0f;
if (fH == 360) fH = 0;
float fS = float(s) / 255.00f;
float fB = float(b) / 255.00f;
float R,G,B;
byte cR,cG,cB;
int i;
float f,p,q,t;
if (fS ==0 )
{
cR = cG = cB = fB;
}
else
{
fH /= 60;
i = floor(fH);
f = fH-i;
p = fB * (1-fS);
q = fB * (1-fS*f);
t = fB * (1-fS * (1-f));
switch(i){
case 0:
R = fB;
G = t;
B = p;
break;
case 1:
R = q;
G = fB;
B = p;
break;
case 2:
R = p;
G = fB;
B = t;
break;
case 3:
R = p;
G = q;
B = fB;
break;
case 4:
R = t;
G = p;
B = fB;
break;
default: // case 5:
R = fB;
G = p;
B = q;
break;
}
cR = byte(R*255);
cG = byte(G*255);
cB = byte(B*255);
}
long color = 0x0;
color = cR;
color = color << 8;
color |= cG;
color = color << 8;
color |= cB;
color &= 0xFFFFFF;
return color;
}
//!Calculates the length checksum and sotres it in the buffer.
uint8_t WaspRFID::lengthCheckSum(uint8_t *dataTX)
{
dataTX[1] = byte(0x100 - dataTX[0]);
}
void Lamp::drawSolid()
{
_ledColors[0] = hsbToRGB(getColorHue() ,getColorSat(),ambBrightness);
_ledColors[1] = hsbToRGB(getColorHue() ,byte(getColorSat()/1.2f),ambBrightness);
}
void DwarfBuf::dwarf_cfa_def_cfa(uint8_t reg, uint8_t offset) {
byte(DW_CFA_def_cfa);
byte(reg);
byte(offset);
}
int
gram_lex(void)
{
static char *paren;
static long paren_max;
long paren_depth;
int c;
long linum;
int bol_was;
int first_was;
string_ty *s;
int token;
int start_of_line = 0;
trace(("gram_lex()\n{\n"));
for (;;)
{
linum = line_number;
bol_was = bol;
first_was = first;
c = byte();
switch (c)
{
case INPUT_EOF:
token = 0;
goto done;
case '\t':
if (!bol_was || within_define)
continue;
sa_open();
for (;;)
{
c = byte();
switch (c)
{
case INPUT_EOF:
case '\n':
break;
case ' ':
case '\t':
case '\f':
#if __STDC__ >= 1
case '\v':
#endif
if (sa_data_length)
sa_char(c);
continue;
default:
sa_char(c);
continue;
}
break;
}
gram_lval.lv_line =
blob_alloc(sa_close(), input_filename(input), linum);
token = COMMAND;
goto done;
case '#':
sa_open();
more_comment:
start_of_line = 1;
for (;;)
{
c = byte();
switch (c)
{
case INPUT_EOF:
case '\n':
break;
case '#':
if (!start_of_line)
sa_char(c);
continue;
case ' ':
case '\t':
case '\f':
#if __STDC__ >= 1
case '\v':
#endif
if (!start_of_line)
sa_char(' ');
continue;
default:
sa_char(c);
start_of_line = 0;
continue;
}
break;
}
if (!first_was)
{
/*
* If the comment did not start at the
* beginning of the line, throw it away.
*/
byte_undo('\n');
continue;
}
token = COMMENT;
if (c == '\n')
{
/*
* Take a peek at the next character.
* If it is '#', we have more comment.
* If it is '\t', we have a code comment.
*/
c = byte();
if (c == '#')
{
sa_char('\n');
goto more_comment;
}
if (c == '\t')
token = COMMAND_COMMENT;
byte_undo(c);
/* need to restore this state, too */
bol = 1;
first = 1;
colon_special = 1;
}
gram_lval.lv_line =
blob_alloc(sa_close(), input_filename(input), linum);
goto done;
case ' ':
case '\f':
#if __STDC__ >= 1
case '\v':
#endif
break;
case '\n':
token = EOLN;
goto done;
case ';':
if (!colon_special)
goto normal;
byte_undo('\t');
bol = 1;
first = 1;
colon_special = 1;
token = EOLN;
goto done;
case ':':
if (!colon_special)
goto normal;
c = byte();
if (c == ':')
{
token = COLON_COLON;
goto done;
}
if (c == '=')
{
token = COLON_EQUALS;
colon_special = 0;
goto done;
}
byte_undo(c);
token = COLON;
goto done;
case '=':
token = EQUALS;
colon_special = 0;
goto done;
case '+':
c = byte();
if (c == '=')
{
token = PLUS_EQUALS;
colon_special = 0;
goto done;
}
byte_undo(c);
c = '+';
/* fall through... */
default:
normal:
sa_open();
paren_depth = 0;
for (;;)
{
switch (c)
{
case INPUT_EOF:
case '\n':
break;
case ' ':
case '\t':
case '\f':
#if __STDC__ >= 1
case '\v':
#endif
if (!within_define && !paren_depth)
break;
sa_char(c);
c = byte();
continue;
case ';':
case ':':
case '=':
if (colon_special && !within_define && !paren_depth)
break;
sa_char(c);
c = byte();
continue;
default:
sa_char(c);
c = byte();
continue;
case '(':
sa_char(c);
if (paren_depth >= paren_max)
{
paren_max = paren_max * 2 + 16;
paren = mem_change_size(paren, paren_max);
}
paren[paren_depth++] = ')';
c = byte();
continue;
case ')':
case '}':
sa_char(c);
if (paren_depth && c == paren[paren_depth - 1])
--paren_depth;
c = byte();
continue;
case '{':
sa_char(c);
if (paren_depth >= paren_max)
{
paren_max = paren_max * 2 + 16;
paren = mem_change_size(paren, paren_max);
}
paren[paren_depth++] = '}';
c = byte();
continue;
}
break;
}
byte_undo(c);
s = sa_close();
if (first_was && (token = reserved(s)) != 0)
{
switch (token)
{
case DEFINE:
str_free(s);
++within_define;
break;
case ENDDEF:
str_free(s);
--within_define;
break;
case IF:
gram_lval.lv_line =
blob_alloc(s, input_filename(input), linum);
break;
case VPATH:
colon_special = 0;
break;
default:
str_free(s);
break;
}
goto done;
}
gram_lval.lv_line = blob_alloc(s, input_filename(input), linum);
token = WORD;
goto done;
}
}
/*
* here for all exits
*/
done:
#ifdef DEBUG
if (token == WORD || token == COMMENT || token == COMMAND)
trace(("text = \"%s\";\n", gram_lval.lv_line->text->str_text));
#endif
trace(("return %d;\n", token));
trace(("}\n"));
return token;
}
void DwarfBuf::dwarf_cfa_same_value(uint8_t reg) {
byte(DW_CFA_same_value);
byte(reg);
}
uint8_t operator[] ( const off_t index ) const { return byte( index ); }
void DwarfBuf::dwarf_cfa_offset_extended_sf(uint8_t reg, int8_t offset) {
byte(DW_CFA_offset_extended_sf);
byte(reg);
byte(offset & 0x7f);
}
bool ReadStack(){
//reset output stack
stack_top = 0;
//get next code
word code;
assert(code_size <= 12);
if(!ReadBits(code_size, code))
return false;
//index of first free entry in table
const word first_entry = clear_code + 2;
//switch, different posibilities for code:
if(code == clear_code+1)
return true; //exit LZW decompression loop
if(code == clear_code){
code_size = init_code_size + 1; //reset code size
next_entry_index = first_entry; //reset Translation Table
prev_code = code; //Prevent next to be added to table.
//restart, to get another code
return ReadStack();
}
word out_code; //0 - 4096
if(code < next_entry_index){
//code is in table
//set code to output
out_code = code;
}else{
//code is not in table
//keep first character of previous output
++stack_top;
//set prev_code to be output
out_code = prev_code;
}
//expand outcode in out_stack
// - Elements up to first_entry are Raw-Codes and are not expanded
// - Table Prefices contain indexes to other codes
// - Table Suffices contain the raw codes to be output
while(out_code >= first_entry){
if(stack_top > 4096)
return false;
//add suffix to output stack
out_stack[stack_top++] = suffix[out_code];
//loop with preffix
out_code = prefix[out_code];
//watch for corruption
if(out_code >= 4096)
out_code = 0;
}
//now outcode is a raw code, add it to output stack
if(stack_top > 4096)
return false;
out_stack[stack_top++] = byte(out_code);
//add new entry to table (prev_code + outcode)
// (except if previous code was a clearcode)
if(prev_code!=clear_code){
//prevent translation table overflow
if(next_entry_index>=4096)
//return false;
next_entry_index = 4095;
prefix[next_entry_index] = prev_code;
suffix[next_entry_index] = byte(out_code);
++next_entry_index;
//increase codesize if next_entry_index is invalid with current codesize
if(next_entry_index >= dword(1<<code_size)){
if(code_size < 12)
++code_size;
}
}
prev_code = code;
return true;
}
// GET_STATE: returns the current state of the switch and prints the state to serial monitor
// RETURN: current state
float InputElement::get_print_byte_state() {
Serial.print(byte(int(output_state)));
return get_state();
}
int sib()
{
return byte();
}
// CIE conversion to gray using integer arithmetic, add 500 to take care of rounding
static const inline byte RgbToGray (RGB_TRIPLE Rgb)
{ return byte((299 * Rgb.Red + 587 * Rgb.Green + 114 * Rgb.Blue + 500) / 1000); }
void NifStream( ShortString const & val, ostream& out, const NifInfo & info ) {
WriteByte( byte(val.str.size() + 1), out );
out.write( val.str.c_str(), std::streamsize(val.str.size()) );
WriteByte( 0, out );
};
void CONFIG::print_config()
{
//use bigest size for buffer
char sbuf[MAX_PASSWORD_LENGTH+1];
byte bbuf=0;
int ibuf=0;
if (CONFIG::read_byte(EP_WIFI_MODE, &bbuf ))
{
if (byte(bbuf)==CLIENT_MODE) Serial.println("Mode: Station");
else if (byte(bbuf)==AP_MODE) Serial.println("Mode: Access Point");
else Serial.println("Mode: ???");
}
else Serial.println("Error reading mode");
if (CONFIG::read_string(EP_SSID, sbuf , MAX_SSID_LENGTH))
{
Serial.print("SSID: ");
Serial.println(sbuf);
}
else Serial.println("Error reading SSID");
//if (CONFIG::read_string(EP_PASSWORD, sbuf , MAX_PASSWORD_LENGTH))Serial.println(sbuf);
if (CONFIG::read_byte(EP_IP_MODE, &bbuf ))
{
if (byte(bbuf)==STATIC_IP_MODE) Serial.println("IP Mode: Static");
else if (byte(bbuf)==DHCP_MODE) Serial.println("IP Mode: DHCP");
else Serial.println("IP mode: ???");
}
else Serial.println("Error reading IP mode");
if (CONFIG::read_buffer(EP_IP_VALUE,(byte *)sbuf , IP_LENGTH))
{
Serial.print("IP: ");
Serial.println(wifi_config.ip2str((byte *)sbuf));
}
else Serial.println("Error reading IP");
if (CONFIG::read_buffer(EP_MASK_VALUE, (byte *)sbuf , IP_LENGTH))
{
Serial.print("Subnet: ");
Serial.println(wifi_config.ip2str((byte *)sbuf));
}
else Serial.println("Error reading subnet");
if (CONFIG::read_buffer(EP_GATEWAY_VALUE, (byte *)sbuf , IP_LENGTH))
{
Serial.print("Gateway : ");
Serial.println(wifi_config.ip2str((byte *)sbuf));
}
else Serial.println("Error reading gateway");
if (CONFIG::read_buffer(EP_BAUD_RATE, (byte *)&ibuf , INTEGER_LENGTH))
{
Serial.print("Baud rate : ");
Serial.println(ibuf);
}
else Serial.println("Error reading baud rate");
if (CONFIG::read_byte(EP_PHY_MODE, &bbuf ))
{
Serial.print("Phy mode : ");
if (byte(bbuf)==PHY_MODE_11B)Serial.println("11b");
else if (byte(bbuf)==PHY_MODE_11G)Serial.println("11g");
else if (byte(bbuf)==PHY_MODE_11N)Serial.println("11n");
else Serial.println("???");
}
else Serial.println("Error reading phy mode");
if (CONFIG::read_byte(EP_SLEEP_MODE, &bbuf ))
{
Serial.print("Sleep mode : ");
if (byte(bbuf)==NONE_SLEEP_T)Serial.println("None");
else if (byte(bbuf)==LIGHT_SLEEP_T)Serial.println("Light");
else if (byte(bbuf)==MODEM_SLEEP_T)Serial.println("Modem");
else Serial.println("???");
}
else Serial.println("Error reading sleep mode");
if (CONFIG::read_byte(EP_CHANNEL, &bbuf ))
{
Serial.print("Channel : ");
Serial.println(byte(bbuf));
}
else Serial.println("Error reading channel");
if (CONFIG::read_byte(EP_AUTH_TYPE, &bbuf ))
{
Serial.print("Authentification : ");
if (byte(bbuf)==AUTH_OPEN)Serial.println("None");
else if (byte(bbuf)==AUTH_WEP)Serial.println("WEP");
else if (byte(bbuf)==AUTH_WPA_PSK)Serial.println("WPA");
else if (byte(bbuf)==AUTH_WPA2_PSK)Serial.println("WPA2");
else if (byte(bbuf)==AUTH_WPA_WPA2_PSK)Serial.println("WPA/WPA2");
else if (byte(bbuf)==AUTH_MAX)Serial.println("Max");
else Serial.println("???");
}
else Serial.println("Error reading authentification");
if (CONFIG::read_byte(EP_SSID_VISIBLE, &bbuf ))
{
Serial.print("SSID visibility: ");
if (bbuf==0)Serial.println("Hidden");
else if (bbuf==1)Serial.println("Visible");
else Serial.println(bbuf);
}
else Serial.println("Error reading SSID visibility");
if (CONFIG::read_buffer(EP_WEB_PORT, (byte *)&ibuf , INTEGER_LENGTH))
{
Serial.print("Web port: ");
Serial.println(ibuf);
}
else Serial.println("Error reading web port");
if (CONFIG::read_buffer(EP_DATA_PORT, (byte *)&ibuf , INTEGER_LENGTH))
{
Serial.print("Data port: ");
Serial.println(ibuf);
}
else Serial.println("Error reading data port");
if (CONFIG::read_byte(EP_REFRESH_PAGE_TIME, &bbuf ))
{
Serial.print("Web page refresh time: ");
Serial.println(byte(bbuf));
}
else Serial.println("Error reading refesh page");
if (CONFIG::read_string(EP_HOSTNAME, sbuf , MAX_HOSTNAME_LENGTH))
{
Serial.print("Hostname : ");
Serial.println(sbuf);
}
else Serial.println("Error reading hostname");
if (CONFIG::read_buffer(EP_XY_FEEDRATE, (byte *)&ibuf , INTEGER_LENGTH))
{
Serial.print("XY feed rate: ");
Serial.println(ibuf);
}
else Serial.println("Error reading XY feed rate");
if (CONFIG::read_buffer(EP_Z_FEEDRATE, (byte *)&ibuf , INTEGER_LENGTH))
{
Serial.print("Z feed rate: ");
Serial.println(ibuf);
}
else Serial.println("Error reading Z feed rate");
if (CONFIG::read_buffer(EP_E_FEEDRATE, (byte *)&ibuf , INTEGER_LENGTH))
{
Serial.print("E feed rate: ");
Serial.println(ibuf);
}
else Serial.println("Error reading E feed rate");
Serial.print("Captive portal : ");
#ifdef CAPTIVE_PORTAL_FEATURE
Serial.println("Enabled");
#else
Serial.println("Disabled");
#endif
Serial.print("SSDP : ");
#ifdef SSDP_FEATURE
Serial.println("Enabled");
#else
Serial.println("Disabled");
#endif
Serial.print("mDNS : ");
#ifdef MDNS_FEATURE
Serial.println("Enabled");
#else
Serial.println("Disabled");
#endif
}
int ECB_DEC(const unsigned char *ct, unsigned char *pt, symmetric_key *skey)
#endif
{
ulong32 s0, s1, s2, s3, t0, t1, t2, t3, *rk;
int Nr, r;
LTC_ARGCHK(pt != NULL);
LTC_ARGCHK(ct != NULL);
LTC_ARGCHK(skey != NULL);
Nr = skey->rijndael.Nr;
rk = skey->rijndael.dK;
/*
* map byte array block to cipher state
* and add initial round key:
*/
LOAD32H(s0, ct ); s0 ^= rk[0];
LOAD32H(s1, ct + 4); s1 ^= rk[1];
LOAD32H(s2, ct + 8); s2 ^= rk[2];
LOAD32H(s3, ct + 12); s3 ^= rk[3];
#ifdef LTC_SMALL_CODE
for (r = 0; ; r++) {
rk += 4;
t0 =
Td0(byte(s0, 3)) ^
Td1(byte(s3, 2)) ^
Td2(byte(s2, 1)) ^
Td3(byte(s1, 0)) ^
rk[0];
t1 =
Td0(byte(s1, 3)) ^
Td1(byte(s0, 2)) ^
Td2(byte(s3, 1)) ^
Td3(byte(s2, 0)) ^
rk[1];
t2 =
Td0(byte(s2, 3)) ^
Td1(byte(s1, 2)) ^
Td2(byte(s0, 1)) ^
Td3(byte(s3, 0)) ^
rk[2];
t3 =
Td0(byte(s3, 3)) ^
Td1(byte(s2, 2)) ^
Td2(byte(s1, 1)) ^
Td3(byte(s0, 0)) ^
rk[3];
if (r == Nr-2) {
break;
}
s0 = t0; s1 = t1; s2 = t2; s3 = t3;
}
rk += 4;
#else
/*
* Nr - 1 full rounds:
*/
r = Nr >> 1;
for (;;) {
t0 =
Td0(byte(s0, 3)) ^
Td1(byte(s3, 2)) ^
Td2(byte(s2, 1)) ^
Td3(byte(s1, 0)) ^
rk[4];
t1 =
Td0(byte(s1, 3)) ^
Td1(byte(s0, 2)) ^
Td2(byte(s3, 1)) ^
Td3(byte(s2, 0)) ^
rk[5];
t2 =
Td0(byte(s2, 3)) ^
Td1(byte(s1, 2)) ^
Td2(byte(s0, 1)) ^
Td3(byte(s3, 0)) ^
rk[6];
t3 =
Td0(byte(s3, 3)) ^
Td1(byte(s2, 2)) ^
Td2(byte(s1, 1)) ^
Td3(byte(s0, 0)) ^
rk[7];
rk += 8;
if (--r == 0) {
break;
}
s0 =
Td0(byte(t0, 3)) ^
Td1(byte(t3, 2)) ^
Td2(byte(t2, 1)) ^
Td3(byte(t1, 0)) ^
rk[0];
s1 =
Td0(byte(t1, 3)) ^
Td1(byte(t0, 2)) ^
Td2(byte(t3, 1)) ^
Td3(byte(t2, 0)) ^
rk[1];
s2 =
Td0(byte(t2, 3)) ^
Td1(byte(t1, 2)) ^
Td2(byte(t0, 1)) ^
Td3(byte(t3, 0)) ^
rk[2];
s3 =
Td0(byte(t3, 3)) ^
Td1(byte(t2, 2)) ^
Td2(byte(t1, 1)) ^
Td3(byte(t0, 0)) ^
rk[3];
}
#endif
/*
* apply last round and
* map cipher state to byte array block:
*/
s0 =
(Td4[byte(t0, 3)] & 0xff000000) ^
(Td4[byte(t3, 2)] & 0x00ff0000) ^
(Td4[byte(t2, 1)] & 0x0000ff00) ^
(Td4[byte(t1, 0)] & 0x000000ff) ^
rk[0];
STORE32H(s0, pt);
s1 =
(Td4[byte(t1, 3)] & 0xff000000) ^
(Td4[byte(t0, 2)] & 0x00ff0000) ^
(Td4[byte(t3, 1)] & 0x0000ff00) ^
(Td4[byte(t2, 0)] & 0x000000ff) ^
rk[1];
STORE32H(s1, pt+4);
s2 =
(Td4[byte(t2, 3)] & 0xff000000) ^
(Td4[byte(t1, 2)] & 0x00ff0000) ^
(Td4[byte(t0, 1)] & 0x0000ff00) ^
(Td4[byte(t3, 0)] & 0x000000ff) ^
rk[2];
STORE32H(s2, pt+8);
s3 =
(Td4[byte(t3, 3)] & 0xff000000) ^
(Td4[byte(t2, 2)] & 0x00ff0000) ^
(Td4[byte(t1, 1)] & 0x0000ff00) ^
(Td4[byte(t0, 0)] & 0x000000ff) ^
rk[3];
STORE32H(s3, pt+12);
return CRYPT_OK;
}
static void _test_set_last_block(void *fixture)
{
uint64_t last_block = NR_BLOCKS - 1;
_set_cycle(fixture, byte(last_block, 0), byte(last_block, T_BLOCK_SIZE));
}
