Commit 7a3e1480 authored by Andrey Filippov's avatar Andrey Filippov

Continue porting pgm_functions

parent 196a40df
...@@ -209,9 +209,11 @@ ...@@ -209,9 +209,11 @@
#include "latency.h" #include "latency.h"
#include "pgm_functions.h" #include "pgm_functions.h"
#include "jpeghead.h" // to program FPGA Huffman tables #include "jpeghead.h" // to program FPGA Huffman tables
#include "x393.h"
#include "legacy_defines.h" // temporarily #include "legacy_defines.h" // temporarily
#include "sensor_i2c.h" #include "sensor_i2c.h"
#include "x393_videomem.h"
#define COLOR_MARGINS 2 // add this many pixels each side
/** /**
* @brief optional debug output macros * @brief optional debug output macros
...@@ -854,8 +856,8 @@ int pgm_window_common (int sensor_port, ///< sensor port number ( ...@@ -854,8 +856,8 @@ int pgm_window_common (int sensor_port, ///< sensor port number (
if (unlikely(thispars->pars[P_ACTUAL_WIDTH] != (width+timestamp_len))) { if (unlikely(thispars->pars[P_ACTUAL_WIDTH] != (width+timestamp_len))) {
SETFRAMEPARS_SET(P_ACTUAL_WIDTH, width+timestamp_len); ///full width for the compressor, including timestamp, but excluding margins SETFRAMEPARS_SET(P_ACTUAL_WIDTH, width+timestamp_len); ///full width for the compressor, including timestamp, but excluding margins
} }
if (unlikely(thispars->pars[P_SENSOR_PIXH] != width+X313_MARGINS)) if (unlikely(thispars->pars[P_SENSOR_PIXH] != width+(2 * COLOR_MARGINS)))
SETFRAMEPARS_SET(P_SENSOR_PIXH, width+X313_MARGINS); ///full width for the sensor (after decimation), including margins SETFRAMEPARS_SET(P_SENSOR_PIXH, width+(2 * COLOR_MARGINS)); ///full width for the sensor (after decimation), including margins
width*=dh; width*=dh;
if (unlikely(thispars->pars[P_WOI_WIDTH] != width)) if (unlikely(thispars->pars[P_WOI_WIDTH] != width))
SETFRAMEPARS_SET(P_WOI_WIDTH, width); // WOI width, as specified (corrected for the sensor if needed) SETFRAMEPARS_SET(P_WOI_WIDTH, width); // WOI width, as specified (corrected for the sensor if needed)
...@@ -878,8 +880,8 @@ int pgm_window_common (int sensor_port, ///< sensor port number ( ...@@ -878,8 +880,8 @@ int pgm_window_common (int sensor_port, ///< sensor port number (
height= ((height/dv)/X313_TILEVERT) * X313_TILEVERT; // divided by dv (before multisensor options) height= ((height/dv)/X313_TILEVERT) * X313_TILEVERT; // divided by dv (before multisensor options)
// suppose minimal height refers to decimated output // suppose minimal height refers to decimated output
while (height < sensor->minHeight) height+=X313_TILEVERT; while (height < sensor->minHeight) height+=X313_TILEVERT;
if (unlikely(thispars->pars[P_SENSOR_PIXV] != height+X313_MARGINS)) if (unlikely(thispars->pars[P_SENSOR_PIXV] != height+(2 * COLOR_MARGINS)))
SETFRAMEPARS_SET(P_SENSOR_PIXV, height+X313_MARGINS); ///full height for the sensor (after decimation), including margins SETFRAMEPARS_SET(P_SENSOR_PIXV, height+(2 * COLOR_MARGINS)); ///full height for the sensor (after decimation), including margins
height*=dv; height*=dv;
pf_stripes = 0; pf_stripes = 0;
pfh = 0; pfh = 0;
...@@ -904,8 +906,8 @@ int pgm_window_common (int sensor_port, ///< sensor port number ( ...@@ -904,8 +906,8 @@ int pgm_window_common (int sensor_port, ///< sensor port number (
left = thispars->pars[P_WOI_LEFT]; left = thispars->pars[P_WOI_LEFT];
if (!oversize) { // in oversize mode let user to specify any margin, including odd ones (bayer shifted) if (!oversize) { // in oversize mode let user to specify any margin, including odd ones (bayer shifted)
if (is_color) left &= 0xfffe; if (is_color) left &= 0xfffe;
if ((left + width + X313_MARGINS) > sensor->clearWidth) { if ((left + width + (2 * COLOR_MARGINS)) > sensor->clearWidth) {
left = sensor->clearWidth - width - X313_MARGINS; left = sensor->clearWidth - width - (2 * COLOR_MARGINS);
if (is_color) left &= 0xfffe; if (is_color) left &= 0xfffe;
} }
if (left & 0x8000) left = 0; if (left & 0x8000) left = 0;
...@@ -921,8 +923,8 @@ int pgm_window_common (int sensor_port, ///< sensor port number ( ...@@ -921,8 +923,8 @@ int pgm_window_common (int sensor_port, ///< sensor port number (
int clearHeight=(sensor->clearHeight-sensor->imageHeight) + thispars->pars[P_SENSOR_HEIGHT]; int clearHeight=(sensor->clearHeight-sensor->imageHeight) + thispars->pars[P_SENSOR_HEIGHT];
if (!oversize) { // in oversize mode let user to specify any margin, including odd ones (bayer shifted) if (!oversize) { // in oversize mode let user to specify any margin, including odd ones (bayer shifted)
if (is_color) top &= 0xfffe; if (is_color) top &= 0xfffe;
if ((top + ((pfh>0)?0:height) + X313_MARGINS) > clearHeight) { if ((top + ((pfh>0)?0:height) + (2 * COLOR_MARGINS)) > clearHeight) {
top = clearHeight - ((pfh>0)?0:height) - X313_MARGINS; top = clearHeight - ((pfh>0)?0:height) - (2 * COLOR_MARGINS);
if (is_color) top &= 0xfffe; if (is_color) top &= 0xfffe;
} }
if (top & 0x8000) top = 0; if (top & 0x8000) top = 0;
...@@ -1109,8 +1111,95 @@ int pgm_sensorin (int sensor_port, ///< sensor port number (0..3 ...@@ -1109,8 +1111,95 @@ int pgm_sensorin (int sensor_port, ///< sensor port number (0..3
///< be applied to, negative - ASAP ///< be applied to, negative - ASAP
///< @return OK - 0, <0 - error ///< @return OK - 0, <0 - error
{ {
#ifndef NC353
x393_sens_mode_t sens_mode = {.d32=0};
MDF3(printk(" frame16=%d\n",frame16));
if (frame16 >= PARS_FRAMES) return -1; // wrong frame
if (FRAMEPAR_MODIFIED(P_BITS)){
sens_mode.bit16 = thispars->pars[P_BITS];
sens_mode.bit16_set = 1;
X393_SEQ_SEND1 (sensor_port, frame16, x393_sens_mode, sens_mode);
MDF3(printk(" X393_SEQ_SEND1(0x%x, 0x%x, x393_sens_mode, 0x%x)\n", sensor_port, frame16, sens_mode.d32));
//TODO: not (yet) implemented
//(thispars->pars[P_FPGATEST]), \
//(thispars->pars[P_FPNS]), \
//(thispars->pars[P_FPNM]), \
//thispars->pars[P_SHIFTL]));
}
//
int n_scan_lines, n_ph_lines, n_pixels;
// New - writing WOI width for internally generated HACT
n_pixels=((thispars->pars[P_ACTUAL_WIDTH]+(2 * COLOR_MARGINS)) & 0x3fff) | 0x4000;
X3X3_SEQ_SEND1 (fpga_addr, X313_WA_NLINES, n_pixels);
MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", fpga_addr, (int) X313_WA_NLINES, (int) n_pixels));
//#define P_FRAMESYNC_DLY 35 ///< maybe - temporary - delay of frame sync (vacts) by number of scan lines - for photofinish mode // not used anywhere?
///< Lower bits 16 will be used to delay frame sync, bit 16 - use internal HACT duration (0 - use from sensor) [*]
//#define P_PF_HEIGHT 36 ///< height of each strip in photofinish mode - normally 2 lines
///< also now includes timestamping mode +0x10000 - for normal frames, 0x20000 - for photo-finish
//#define P_BITS 37 ///< pixel depth - bits 10/8/4
/*
Change bit16 only without histograms
typedef union {
struct {
u32 hist_en: 4; // [ 3: 0] (0xf) Enable subchannel histogram modules (may be less than 4)
u32 hist_nrst: 4; // [ 7: 4] (0xf) Reset off for histograms subchannels (may be less than 4)
u32 hist_set: 1; // [ 8] (0) Apply values in hist_en and hist_nrst fields (0 - ignore)
u32 chn_en: 1; // [ 9] (1) Enable this sensor channel
u32 chn_en_set: 1; // [ 10] (1) Apply chn_en value (0 - ignore)
u32 bit16: 1; // [ 11] (0) 0 - 8 bpp mode, 1 - 16 bpp (bypass gamma). Gamma-processed data is still used for histograms
u32 bit16_set: 1; // [ 12] (0) Apply bit16 value (0 - ignore)
u32 :19;
};
struct {
u32 d32:32; // [31: 0] (0) cast to u32
};
} x393_sens_mode_t;
*/
// Program number of scan lines to acquire
// Is PhotoFinish mode enabled? // **************** TODO: use ACTUAL_HEIGHT (and update it) not WOI_HEIGHT
if (((thispars->pars[P_PF_HEIGHT] & 0xffff)>0) && (thispars->pars[P_PF_HEIGHT]<=thispars->pars[P_ACTUAL_HEIGHT])){
n_ph_lines= thispars->pars[P_ACTUAL_HEIGHT]/(thispars->pars[P_PF_HEIGHT] & 0x3fff);
MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", fpga_addr, (int) X313_WA_NLINES, (int) (n_ph_lines-1) | 0x8000));
X3X3_SEQ_SEND1 (fpga_addr, X313_WA_NLINES, (n_ph_lines-1) | 0x8000);
// n_scan_lines= thispars->pars[P_PF_HEIGHT];
n_scan_lines= thispars->pars[P_ACTUAL_HEIGHT]; // no margins here
} else {
// temporary hack trying to disable PH mode earlier
MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", X313_SEQ_ASAP, X313_WA_NLINES, 0x8000));
X3X3_SEQ_SEND1 (X313_SEQ_ASAP, X313_WA_NLINES, 0x8000);
n_scan_lines= thispars->pars[P_ACTUAL_HEIGHT]+(2 * COLOR_MARGINS)+thispars->pars[P_OVERLAP];
}
n_scan_lines&=0x3fff;
X3X3_SEQ_SEND1 (fpga_addr, X313_WA_NLINES, n_scan_lines);
MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", fpga_addr, (int) X313_WA_NLINES, (int) n_scan_lines));
// Bayer phase changed?
int flips=(thispars->pars[P_FLIPH] & 1) | ((thispars->pars[P_FLIPV] & 1)<<1);
int bayer_modified=FRAMEPAR_MODIFIED(P_BAYER) || FRAMEPAR_MODIFIED(P_FLIPH) || FRAMEPAR_MODIFIED(P_FLIPV) || FRAMEPAR_MODIFIED(P_MULTI_MODE);
MDF3(printk(" flips=%x\n", flips));
if (thispars->pars[P_MULTI_MODE]) { // Modify flips in composite mode - should match flips of the top (direct) channel
int this_bit=(1<<thispars->pars[P_MULTI_TOPSENSOR]);
if (thispars->pars[P_MULTI_FLIPH] & this_bit) flips^=1;
if (thispars->pars[P_MULTI_FLIPV] & this_bit) flips^=2;
MDF3(printk(" composite mode - adjusted flips=%x\n", flips));
bayer_modified= bayer_modified || FRAMEPAR_MODIFIED(P_MULTI_FLIPH) || FRAMEPAR_MODIFIED(P_MULTI_FLIPV) || FRAMEPAR_MODIFIED(P_MULTI_TOPSENSOR);
}
if (bayer_modified) {
X3X3_SEQ_SEND1(fpga_addr, X313_WA_DCR0, X353_DCR0(BAYER_PHASE,thispars->pars[P_BAYER] ^ flips ^ sensor->bayer)); ///NOTE: hardware bayer
MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", fpga_addr, (int)X313_WA_DCR0, (int)X353_DCR0(BAYER_PHASE,thispars->pars[P_BAYER] ^ ((thispars->pars[P_FLIPH] & 1) | ((thispars->pars[P_FLIPV] & 1)<<1)) ^ sensor->bayer) ));
}
return 0;
#else
MDF3(printk(" frame16=%d\n",frame16)); MDF3(printk(" frame16=%d\n",frame16));
#ifdef NC353
if (frame16 >= PARS_FRAMES) return -1; // wrong frame if (frame16 >= PARS_FRAMES) return -1; // wrong frame
int fpga_addr=(frame16 <0) ? X313_SEQ_ASAP : (X313_SEQ_FRAME0+frame16); int fpga_addr=(frame16 <0) ? X313_SEQ_ASAP : (X313_SEQ_FRAME0+frame16);
// Set FPN mode (P_FPGATEST - currently only LSB is processed) // Set FPN mode (P_FPGATEST - currently only LSB is processed)
...@@ -1131,7 +1220,7 @@ int pgm_sensorin (int sensor_port, ///< sensor port number (0..3 ...@@ -1131,7 +1220,7 @@ int pgm_sensorin (int sensor_port, ///< sensor port number (0..3
int n_scan_lines, n_ph_lines, n_pixels; int n_scan_lines, n_ph_lines, n_pixels;
// New - writing WOI width for internally generated HACT // New - writing WOI width for internally generated HACT
n_pixels=((thispars->pars[P_ACTUAL_WIDTH]+X313_MARGINS) & 0x3fff) | 0x4000; n_pixels=((thispars->pars[P_ACTUAL_WIDTH]+(2 * COLOR_MARGINS)) & 0x3fff) | 0x4000;
X3X3_SEQ_SEND1 (fpga_addr, X313_WA_NLINES, n_pixels); X3X3_SEQ_SEND1 (fpga_addr, X313_WA_NLINES, n_pixels);
MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", fpga_addr, (int) X313_WA_NLINES, (int) n_pixels)); MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", fpga_addr, (int) X313_WA_NLINES, (int) n_pixels));
...@@ -1150,7 +1239,7 @@ int pgm_sensorin (int sensor_port, ///< sensor port number (0..3 ...@@ -1150,7 +1239,7 @@ int pgm_sensorin (int sensor_port, ///< sensor port number (0..3
MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", X313_SEQ_ASAP, X313_WA_NLINES, 0x8000)); MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", X313_SEQ_ASAP, X313_WA_NLINES, 0x8000));
X3X3_SEQ_SEND1 (X313_SEQ_ASAP, X313_WA_NLINES, 0x8000); X3X3_SEQ_SEND1 (X313_SEQ_ASAP, X313_WA_NLINES, 0x8000);
n_scan_lines= thispars->pars[P_ACTUAL_HEIGHT]+X313_MARGINS+thispars->pars[P_OVERLAP]; n_scan_lines= thispars->pars[P_ACTUAL_HEIGHT]+(2 * COLOR_MARGINS)+thispars->pars[P_OVERLAP];
} }
n_scan_lines&=0x3fff; n_scan_lines&=0x3fff;
X3X3_SEQ_SEND1 (fpga_addr, X313_WA_NLINES, n_scan_lines); X3X3_SEQ_SEND1 (fpga_addr, X313_WA_NLINES, n_scan_lines);
...@@ -1173,8 +1262,8 @@ int pgm_sensorin (int sensor_port, ///< sensor port number (0..3 ...@@ -1173,8 +1262,8 @@ int pgm_sensorin (int sensor_port, ///< sensor port number (0..3
MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", fpga_addr, (int)X313_WA_DCR0, (int)X353_DCR0(BAYER_PHASE,thispars->pars[P_BAYER] ^ ((thispars->pars[P_FLIPH] & 1) | ((thispars->pars[P_FLIPV] & 1)<<1)) ^ sensor->bayer) )); MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", fpga_addr, (int)X313_WA_DCR0, (int)X353_DCR0(BAYER_PHASE,thispars->pars[P_BAYER] ^ ((thispars->pars[P_FLIPH] & 1) | ((thispars->pars[P_FLIPV] & 1)<<1)) ^ sensor->bayer) ));
} }
#endif
return 0; return 0;
#endif
} }
/** Start/single acquisition from the sensor to the FPGA (stop has latency of 1) /** Start/single acquisition from the sensor to the FPGA (stop has latency of 1)
...@@ -1425,41 +1514,60 @@ int pgm_memsensor (int sensor_port, ///< sensor port number ( ...@@ -1425,41 +1514,60 @@ int pgm_memsensor (int sensor_port, ///< sensor port number (
///< be applied to, negative - ASAP ///< be applied to, negative - ASAP
///< @return OK - 0, <0 - error ///< @return OK - 0, <0 - error
{ {
#ifndef NC353
int width_marg, height_marg, width_bursts;
MDF3(printk(" frame16=%d\n",frame16));
if (frame16 >= PARS_FRAMES) return -1; // wrong frame
width_marg = thispars->pars[P_ACTUAL_WIDTH];
height_marg = thispars->pars[P_ACTUAL_WIDTH];
switch(thispars->pars[P_COLOR]){
case COLORMODE_COLOR:
case COLORMODE_COLOR20:
width_marg += (2 * COLOR_MARGINS);
if ((thispars->pars[P_PF_HEIGHT] & 0xffff)==0) { // not a photofinish
height_marg += (2 * COLOR_MARGINS);
}
break;
}
width_bursts = (width_marg >> 4) + ((width_marg & 0xf) ? 1 : 0);
setup_sensor_memory (sensor_port, // sensor port number (0..3)
width_bursts, // 13-bit - in 8*16=128 bit bursts
height_marg, // 16-bit window height (in scan lines)
0, // 13-bit window left margin in 8-bursts (16 bytes)
0, // 16-bit window top margin (in scan lines
(frame16<0)? ASAP: ABSOLUTE, // how to apply commands - directly or through channel sequencer
frame16); // Frame number the command should be applied to (if not immediate mode)
return 0;
#else
int ntilex,ntiley,goodEOL,padlen, imgsz,sa; int ntilex,ntiley,goodEOL,padlen, imgsz,sa;
MDF3(printk(" frame16=%d\n",frame16)); MDF3(printk(" frame16=%d\n",frame16));
if (frame16 >= PARS_FRAMES) return -1; // wrong frame if (frame16 >= PARS_FRAMES) return -1; // wrong frame
#ifdef NC353
int fpga_addr=(frame16 <0) ? X313_SEQ_ASAP : (X313_SEQ_FRAME0+frame16); int fpga_addr=(frame16 <0) ? X313_SEQ_ASAP : (X313_SEQ_FRAME0+frame16);
#endif //NC393 - use margins of 2 pixels from each side for color JPEG (even for JPEG18) to preserve Bayer
///programm channel1 (FPN). Will not enable if not needed (imageParamsR[P_FPN]==0) ///programm channel1 (FPN). Will not enable if not needed (imageParamsR[P_FPN]==0)
ntilex=((thispars->pars[P_ACTUAL_WIDTH]+X313_MARGINS+7)>>3); ntilex=((thispars->pars[P_ACTUAL_WIDTH]+(2 * COLOR_MARGINS)+7)>>3);
ntiley=thispars->pars[P_ACTUAL_HEIGHT]+(((thispars->pars[P_PF_HEIGHT] & 0xffff)>0)?0:X313_MARGINS); ntiley=thispars->pars[P_ACTUAL_HEIGHT]+(((thispars->pars[P_PF_HEIGHT] & 0xffff)>0)?0:(2 * COLOR_MARGINS));
MDF3(printk("ntilex=0x%x ntiley=0x%x\n",ntilex,ntiley)); MDF3(printk("ntilex=0x%x ntiley=0x%x\n",ntilex,ntiley));
if ((thispars->pars[P_PF_HEIGHT] & 0xffff)==0) { // not a photofinish if ((thispars->pars[P_PF_HEIGHT] & 0xffff)==0) { // not a photofinish
if(!thispars->pars[P_BGFRAME] && ((thispars->pars[P_FPNS]!=0) || (thispars->pars[P_FPNM]!=0))) { if(!thispars->pars[P_BGFRAME] && ((thispars->pars[P_FPNS]!=0) || (thispars->pars[P_FPNM]!=0))) {
// program memory channel1 // program memory channel1
#ifdef NC353
X3X3_SEQ_SEND1(fpga_addr, X313_WA_SDCH1_CTL1, X313_SDCHAN_REG1(0,0,0, X313_MAP_FPN, (ntilex-1), (ntiley-1))); X3X3_SEQ_SEND1(fpga_addr, X313_WA_SDCH1_CTL1, X313_SDCHAN_REG1(0,0,0, X313_MAP_FPN, (ntilex-1), (ntiley-1)));
X3X3_SEQ_SEND1(fpga_addr, X313_WA_SDCH1_CTL2, X313_SDCHAN_REG2(0,0,0, X313_MAP_FPN, (ntilex-1), (ntiley-1))); X3X3_SEQ_SEND1(fpga_addr, X313_WA_SDCH1_CTL2, X313_SDCHAN_REG2(0,0,0, X313_MAP_FPN, (ntilex-1), (ntiley-1)));
X3X3_SEQ_SEND1(fpga_addr, X313_WA_SDCH1_CTL0, X313_SDCHAN_REG0(0,0,0, X313_MAP_FPN, (ntilex-1), (ntiley-1))); X3X3_SEQ_SEND1(fpga_addr, X313_WA_SDCH1_CTL0, X313_SDCHAN_REG0(0,0,0, X313_MAP_FPN, (ntilex-1), (ntiley-1)));
// enable channel1 for reading SDRAM // enable channel1 for reading SDRAM
X3X3_SEQ_SEND1(fpga_addr, X313_WA_SD_MODE, X313_CHN_EN_D(1)); // wait ready later... ??? X3X3_SEQ_SEND1(fpga_addr, X313_WA_SD_MODE, X313_CHN_EN_D(1)); // wait ready later... ???
#endif
MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", fpga_addr, (int) X313_WA_SDCH1_CTL1, (int) X313_SDCHAN_REG1(0,0,0, X313_MAP_FPN, (ntilex-1), (ntiley-1)))); MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", fpga_addr, (int) X313_WA_SDCH1_CTL1, (int) X313_SDCHAN_REG1(0,0,0, X313_MAP_FPN, (ntilex-1), (ntiley-1))));
MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", fpga_addr, (int) X313_WA_SDCH1_CTL2, (int) X313_SDCHAN_REG2(0,0,0, X313_MAP_FPN, (ntilex-1), (ntiley-1)))); MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", fpga_addr, (int) X313_WA_SDCH1_CTL2, (int) X313_SDCHAN_REG2(0,0,0, X313_MAP_FPN, (ntilex-1), (ntiley-1))));
MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", fpga_addr, (int) X313_WA_SDCH1_CTL0, (int) X313_SDCHAN_REG0(0,0,0, X313_MAP_FPN, (ntilex-1), (ntiley-1)))); MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", fpga_addr, (int) X313_WA_SDCH1_CTL0, (int) X313_SDCHAN_REG0(0,0,0, X313_MAP_FPN, (ntilex-1), (ntiley-1))));
MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", fpga_addr, (int) X313_WA_SD_MODE, (int) X313_CHN_EN_D(1))); MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", fpga_addr, (int) X313_WA_SD_MODE, (int) X313_CHN_EN_D(1)));
} else { } else {
#ifdef NC353
X3X3_SEQ_SEND1(fpga_addr, X313_WA_SD_MODE, X313_CHN_DIS_D(1)); X3X3_SEQ_SEND1(fpga_addr, X313_WA_SD_MODE, X313_CHN_DIS_D(1));
#endif
MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", fpga_addr, (int) X313_WA_SD_MODE, (int) X313_CHN_DIS_D(1))); MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", fpga_addr, (int) X313_WA_SD_MODE, (int) X313_CHN_DIS_D(1)));
} }
} else { } else {
#ifdef NC353
X3X3_SEQ_SEND1(fpga_addr, X313_WA_SD_MODE, X313_CHN_DIS_D(1)); X3X3_SEQ_SEND1(fpga_addr, X313_WA_SD_MODE, X313_CHN_DIS_D(1));
#endif
MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", fpga_addr, (int) X313_WA_SD_MODE, (int) X313_CHN_DIS_D(1))); MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", fpga_addr, (int) X313_WA_SD_MODE, (int) X313_CHN_DIS_D(1)));
} }
// Program channel 0 (sensor->memory) // Program channel 0 (sensor->memory)
...@@ -1470,7 +1578,7 @@ int pgm_memsensor (int sensor_port, ///< sensor port number ( ...@@ -1470,7 +1578,7 @@ int pgm_memsensor (int sensor_port, ///< sensor port number (
// When reading 20x20 macroblocks to the compressor, such exception is not needed, it crosses page boundaries when needed // When reading 20x20 macroblocks to the compressor, such exception is not needed, it crosses page boundaries when needed
if ((thispars->pars[P_BITS]==8) && (!thispars->pars[P_BGFRAME])) { // in 16-bit mode ntilex will stay the same if ((thispars->pars[P_BITS]==8) && (!thispars->pars[P_BGFRAME])) { // in 16-bit mode ntilex will stay the same
ntilex=((thispars->pars[P_ACTUAL_WIDTH]+X313_MARGINS+15)>>4); ntilex=((thispars->pars[P_ACTUAL_WIDTH]+(2 * COLOR_MARGINS)+15)>>4);
goodEOL=((thispars->pars[P_ACTUAL_WIDTH] & 0x0f) == 0) && ((thispars->pars[P_ACTUAL_WIDTH] & 0x1f0) != 0); goodEOL=((thispars->pars[P_ACTUAL_WIDTH] & 0x0f) == 0) && ((thispars->pars[P_ACTUAL_WIDTH] & 0x1f0) != 0);
if (goodEOL) ntilex--; if (goodEOL) ntilex--;
MDF3(printk("ntilex=0x%x ntiley=0x%x goodEOL=0x%x\n",ntilex,ntiley,goodEOL)); MDF3(printk("ntilex=0x%x ntiley=0x%x goodEOL=0x%x\n",ntilex,ntiley,goodEOL));
...@@ -1481,11 +1589,10 @@ int pgm_memsensor (int sensor_port, ///< sensor port number ( ...@@ -1481,11 +1589,10 @@ int pgm_memsensor (int sensor_port, ///< sensor port number (
if (thispars->pars[P_OVERLAP]>0) ntiley=(ntiley<<1); // ntiley will be twice bigger for synch. mode) if (thispars->pars[P_OVERLAP]>0) ntiley=(ntiley<<1); // ntiley will be twice bigger for synch. mode)
padlen=((ntilex+31)>>5) << 8; padlen=((ntilex+31)>>5) << 8;
//TODO:fix it to be able to use two (or larger) frame buffer //TODO:fix it to be able to use two (or larger) frame buffer
// imgsz=((padlen * (thispars->pars[P_ACTUAL_HEIGHT]+X313_MARGINS) * thispars->pars[P_PAGE_ACQ]) << ((thispars->pars(P_TRIG) & 1)?1:0)); // mostly rotten too // imgsz=((padlen * (thispars->pars[P_ACTUAL_HEIGHT]+(2 * COLOR_MARGINS)) * thispars->pars[P_PAGE_ACQ]) << ((thispars->pars(P_TRIG) & 1)?1:0)); // mostly rotten too
imgsz=padlen * ntiley; imgsz=padlen * ntiley;
MDF3(printk("imgsz=0x%x, padlen=0x%x\n",imgsz,padlen)); MDF3(printk("imgsz=0x%x, padlen=0x%x\n",imgsz,padlen));
if (thispars->pars[P_IMGSZMEM]!= imgsz) setFramePar(sensor_port, thispars, P_IMGSZMEM, imgsz); // set it (and propagate to the later frames) if (thispars->pars[P_IMGSZMEM]!= imgsz) setFramePar(sensor_port, thispars, P_IMGSZMEM, imgsz); // set it (and propagate to the later frames)
#ifdef NC353
sa=X313_MAP_FRAME + (imgsz * thispars->pars[P_PAGE_ACQ]); // now - always X313_MAP_FRAME sa=X313_MAP_FRAME + (imgsz * thispars->pars[P_PAGE_ACQ]); // now - always X313_MAP_FRAME
X3X3_SEQ_SEND1(fpga_addr, X313_WA_SDCH0_CTL1, X313_SDCHAN_REG1(0,1,1, sa, (ntilex-1), (ntiley-1))); X3X3_SEQ_SEND1(fpga_addr, X313_WA_SDCH0_CTL1, X313_SDCHAN_REG1(0,1,1, sa, (ntilex-1), (ntiley-1)));
MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", fpga_addr, (int) X313_WA_SDCH0_CTL1, (int) X313_SDCHAN_REG1(0,1,1, sa, (ntilex-1), (ntiley-1)) )); MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", fpga_addr, (int) X313_WA_SDCH0_CTL1, (int) X313_SDCHAN_REG1(0,1,1, sa, (ntilex-1), (ntiley-1)) ));
...@@ -1495,9 +1602,10 @@ int pgm_memsensor (int sensor_port, ///< sensor port number ( ...@@ -1495,9 +1602,10 @@ int pgm_memsensor (int sensor_port, ///< sensor port number (
MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", fpga_addr, (int) X313_WA_SDCH0_CTL0, (int) X313_SDCHAN_REG0(0,1,1, sa, (ntilex-1), (ntiley-1)) )); MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", fpga_addr, (int) X313_WA_SDCH0_CTL0, (int) X313_SDCHAN_REG0(0,1,1, sa, (ntilex-1), (ntiley-1)) ));
X3X3_SEQ_SEND1(fpga_addr, X313_WA_SD_MODE, X313_CHN_EN_D(0)); X3X3_SEQ_SEND1(fpga_addr, X313_WA_SD_MODE, X313_CHN_EN_D(0));
MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", fpga_addr, (int) X313_WA_SD_MODE, (int) X313_CHN_EN_D(0) )); MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", fpga_addr, (int) X313_WA_SD_MODE, (int) X313_CHN_EN_D(0) ));
#endif
// number of scan lines to read from sensor - program in pgm_sensorin // number of scan lines to read from sensor - program in pgm_sensorin
return 0; return 0;
#endif
} }
/** Program memory channel 2 (memory->compressor) /** Program memory channel 2 (memory->compressor)
...@@ -1514,7 +1622,66 @@ int pgm_memcompressor (int sensor_port, ///< sensor port number ( ...@@ -1514,7 +1622,66 @@ int pgm_memcompressor (int sensor_port, ///< sensor port number (
///< @return OK - 0, <0 - error ///< @return OK - 0, <0 - error
{ {
//TODO: redo for nc393 //TODO: redo for nc393
#ifdef NC353 #ifndef NC353
int width_marg, height_marg;
int overlap; // tile overlap (total - 2 for JPEG18, 4 - for JPEG20, 0 otherwise
int width_bursts;
int cmprs_top = 0; // 1 for JPEG18 only, 0 for others
int tile_width; // in bursts, 2 for those with overlap (height>16), 4 with heigh==16
int tile_height; // 16/18 (20 not yet implemented)
int extra_pages; // 1 with overlap, 0 w/o overlap
int disable_need = 1; // TODO: Use some G_* parameter
MDF3(printk(" frame16=%d\n",frame16));
if (frame16 >= PARS_FRAMES) return -1; // wrong frame
width_marg = thispars->pars[P_ACTUAL_WIDTH];
height_marg = thispars->pars[P_ACTUAL_WIDTH];
switch(thispars->pars[P_COLOR]){
case COLORMODE_COLOR:
overlap = 2;
cmprs_top = 1;
break;
case COLORMODE_COLOR20:
overlap = 4;
break;
}
if (overlap){
width_marg += (2 * COLOR_MARGINS);
if ((thispars->pars[P_PF_HEIGHT] & 0xffff)==0) { // not a photofinish
height_marg += (2 * COLOR_MARGINS);
}
tile_width = 2;
extra_pages = 1;
} else {
tile_width = 4;
extra_pages = 0;
}
width_bursts = (width_marg >> 4) + ((width_marg & 0xf) ? 1 : 0);
// Adjusting for tile width. TODO: probably not needed, handled in FPGA - verify (and remove 2 next lines)
if (width_bursts & 1) width_bursts++;
if ((tile_width>2) && (width_bursts & 2)) width_bursts += 2;
tile_height = 16 + overlap;
setup_compressor_memory (sensor_port, // sensor port number (0..3)
width_bursts, // 13-bit - in 8*16=128 bit bursts
height_marg, // 16-bit window height (in scan lines)
0, // 13-bit window left margin in 8-bursts (16 bytes)
cmprs_top, // 16-bit window top margin (in scan lines
tile_width, // tile width in bjursts (16-pixels each)
tile_height, // tile height: 18 for color JPEG, 16 for JP4 flavors // = 18
16, // tile vertical step in pixel rows (JPEG18/jp4 = 16) // = 16
extra_pages, // extra pages needed (1) - number of previous pages to keep in a 4-page buffer
disable_need, // disable "need" (yield to sensor channels - they can not wait)
(frame16<0)? ASAP: ABSOLUTE, // how to apply commands - directly or through channel sequencer
frame16); // Frame number the command should be applied to (if not immediate mode)
return 0;
// TODO: Do we need to maintain P_IMGSZMEM ?
// #define P_PAGE_ACQ 18 ///< Number of image page buffer to acquire to (0.1?)
// #define P_PAGE_READ 19 ///< Number of image page buffer to read from to (0.1?)
#else
int ntilex,ntiley,sa,pf; int ntilex,ntiley,sa,pf;
// struct frameparspair_t * pars_to_update[4]={ // struct frameparspair_t * pars_to_update[4]={
struct frameparspair_t pars_to_update[4]={ struct frameparspair_t pars_to_update[4]={
...@@ -1526,11 +1693,9 @@ int pgm_memcompressor (int sensor_port, ///< sensor port number ( ...@@ -1526,11 +1693,9 @@ int pgm_memcompressor (int sensor_port, ///< sensor port number (
MDF3(printk(" frame16=%d\n",frame16)); MDF3(printk(" frame16=%d\n",frame16));
if (frame16 >= PARS_FRAMES) return -1; // wrong frame if (frame16 >= PARS_FRAMES) return -1; // wrong frame
// int fpga_addr=(frame16 <0) ? X313_SEQ_ASAP : (X313_SEQ_FRAME0+frame16); // int fpga_addr=(frame16 <0) ? X313_SEQ_ASAP : (X313_SEQ_FRAME0+frame16);
ntilex=((thispars->pars[P_ACTUAL_WIDTH]+X313_MARGINS-1)>>4); ntilex=((thispars->pars[P_ACTUAL_WIDTH]+(2 * COLOR_MARGINS)-1)>>4);
ntiley=thispars->pars[P_ACTUAL_HEIGHT]; // number of lines it the whole frame ntiley=thispars->pars[P_ACTUAL_HEIGHT]; // number of lines it the whole frame
#ifdef NC353
sa=X313_MAP_FRAME + ( thispars->pars[P_IMGSZMEM] * thispars->pars[P_PAGE_READ]); // now - always X313_MAP_FRAME sa=X313_MAP_FRAME + ( thispars->pars[P_IMGSZMEM] * thispars->pars[P_PAGE_READ]); // now - always X313_MAP_FRAME
#endif
pf=((thispars->pars[P_PF_HEIGHT] & 0xffff)>0)?1:0; // when mode==1, wnr means "photofinish" in fpga pf=((thispars->pars[P_PF_HEIGHT] & 0xffff)>0)?1:0; // when mode==1, wnr means "photofinish" in fpga
int depend=((thispars->pars[P_SENSOR_RUN] & 3)==SENSOR_RUN_STOP) ? 0 : 1; int depend=((thispars->pars[P_SENSOR_RUN] & 3)==SENSOR_RUN_STOP) ? 0 : 1;
MDF23(printk("ntilex=0x%x ntiley=0x%x sa=0x%x pf=0x%x depend=%x\n",ntilex,ntiley,sa,pf,depend)); MDF23(printk("ntilex=0x%x ntiley=0x%x sa=0x%x pf=0x%x depend=%x\n",ntilex,ntiley,sa,pf,depend));
...@@ -1542,8 +1707,8 @@ int pgm_memcompressor (int sensor_port, ///< sensor port number ( ...@@ -1542,8 +1707,8 @@ int pgm_memcompressor (int sensor_port, ///< sensor port number (
pars_to_update[3].val=ntilex*(ntiley>>4); pars_to_update[3].val=ntilex*(ntiley>>4);
setFramePars(sensor_port, thispars, 4, pars_to_update); setFramePars(sensor_port, thispars, 4, pars_to_update);
#endif
return 0; return 0;
#endif
} }
...@@ -1557,9 +1722,103 @@ int pgm_compmode (int sensor_port, ///< sensor port number (0..3 ...@@ -1557,9 +1722,103 @@ int pgm_compmode (int sensor_port, ///< sensor port number (0..3
///< be applied to, negative - ASAP ///< be applied to, negative - ASAP
///< @return OK - 0, <0 - error ///< @return OK - 0, <0 - error
{ {
int comp_cmd=0;
struct frameparspair_t pars_to_update[4]; // 2 needed, increase if more entries will be added struct frameparspair_t pars_to_update[4]; // 2 needed, increase if more entries will be added
int nupdate=0; int nupdate=0;
int csb;
int csr;
#ifndef NC353
int comp_cmd=0;
// x393cmd_t x393cmd;
x393_cmprs_mode_t cmprs_mode = {.d32=0};
x393_cmprs_colorsat_t cmprs_colorsat = {.d32=0};
x393_cmprs_coring_mode_t cmprs_coring_mode = {.d32=0};
MDF3(printk(" frame16=%d\n",frame16));
if (!jpeg_htable_is_programmed(sensor_port)) jpeg_htable_fpga_pgm (sensor_port);
if (frame16 >= PARS_FRAMES) return -1; // wrong frame
// x393cmd = (frame16<0)? ASAP: ABSOLUTE;
if (FRAMEPAR_MODIFIED(P_COLOR)) {
switch (thispars->pars[P_COLOR] & 0x0f){
case COLORMODE_MONO6: cmprs_mode.cmode = X393_CMPRS_CBIT_CMODE_MONO6; break;
case COLORMODE_COLOR: cmprs_mode.cmode = X393_CMPRS_CBIT_CMODE_JPEG18; break;
case COLORMODE_JP46: cmprs_mode.cmode = X393_CMPRS_CBIT_CMODE_JP46; break;
case COLORMODE_JP46DC: cmprs_mode.cmode = X393_CMPRS_CBIT_CMODE_JP46DC; break;
case COLORMODE_COLOR20: cmprs_mode.cmode = X393_CMPRS_CBIT_CMODE_JPEG20; break; //NOT implemented
case COLORMODE_JP4: cmprs_mode.cmode = X393_CMPRS_CBIT_CMODE_JP4; break;
case COLORMODE_JP4DC: cmprs_mode.cmode = X393_CMPRS_CBIT_CMODE_JP4DC; break;
case COLORMODE_JP4DIFF: cmprs_mode.cmode = X393_CMPRS_CBIT_CMODE_JP4DIFF; break;
case COLORMODE_JP4HDR: cmprs_mode.cmode = X393_CMPRS_CBIT_CMODE_JP4DIFFHDR; break;
case COLORMODE_JP4DIFF2: cmprs_mode.cmode = X393_CMPRS_CBIT_CMODE_JP4DIFFDIV2; break;
case COLORMODE_JP4HDR2: cmprs_mode.cmode = X393_CMPRS_CBIT_CMODE_JP4DIFFHDRDIV2; break;
case COLORMODE_MONO4: cmprs_mode.cmode = X393_CMPRS_CBIT_CMODE_MONO4; break;
}
cmprs_mode.cmode_set = 1;
// TODO: Modify left margin by 1 for COLORMODE_COLOR !
}
// Bayer shift changed? (additional bayer shift, separate from the gamma-tables one)
if (FRAMEPAR_MODIFIED(P_COMPMOD_BYRSH)) {
cmprs_mode.bayer = thispars->pars[P_COMPMOD_BYRSH];
cmprs_mode.bayer_set = 1;
}
#if 0
// Tile shift changed? (position of the 16x16, 18x8 or 20x20 inside 20x20 overlapping tile - dx==dy (diagonal), 0..4)
if (FRAMEPAR_MODIFIED(P_COMPMOD_TILSH)) {
comp_cmd |= COMPCMD_TILESHIFT(thispars->pars[P_COMPMOD_TILSH]);
}
#endif
// DC subtraction modse changed? (mostly FPGA debug feature, normally should be on - average block level to bypass DCT conversion)
if (FRAMEPAR_MODIFIED(P_COMPMOD_DCSUB)) {
cmprs_mode.dcsub = thispars->pars[P_COMPMOD_DCSUB];
cmprs_mode.dcsub_set = 1;
}
// Did focus show mode change? (do it here, not with other focus parameters that can not be set through the sequencer (writing tables
// could break writing gamma/quantization/whatever tables . Is it applicable to NC393?
if (FRAMEPAR_MODIFIED(P_FOCUS_SHOW)) {
cmprs_mode.focus = thispars->pars[P_FOCUS_SHOW];
cmprs_mode.focus_set = 1;
}
// enqueue it for the compressor
//#define X393_SEQ_SEND1(port,frame,func,data) {if ((frame) < 0) seqr_##func (0, (data), (port)); \
// else seqa_##func ((frame), (data), (port)); }
//if (frame16 < 0) seqr_x393_cmprs_control_reg (0, cmprs_mode, sensor_port);
//else seqa_x393_cmprs_control_reg (frame16, cmprs_mode, sensor_port);
if (cmprs_mode.d32) {
X393_SEQ_SEND1 (sensor_port, frame16, x393_cmprs_control_reg, cmprs_mode);
MDF3(printk(" X393_SEQ_SEND1(0x%x, 0x%x, x393_cmprs_control_reg, 0x%x)\n", sensor_port, frame16, cmprs_mode.d32));
} else {
MDF3(printk(" comp_cmd.d32==0, does not need to be sent\n"));
}
// color saturation changed?
if (FRAMEPAR_MODIFIED(P_COLOR_SATURATION_BLUE) || FRAMEPAR_MODIFIED(P_COLOR_SATURATION_RED)) {
csb=(thispars->pars[P_COLOR_SATURATION_BLUE]* DEFAULT_COLOR_SATURATION_BLUE)/100;
csr=(thispars->pars[P_COLOR_SATURATION_RED] * DEFAULT_COLOR_SATURATION_RED)/100;
if (unlikely(csb>1023)) {
csb=102300/DEFAULT_COLOR_SATURATION_BLUE;
SETFRAMEPARS_SET(P_COLOR_SATURATION_BLUE, csb);
}
if (unlikely(csr>1023)) {
csr=102300/DEFAULT_COLOR_SATURATION_RED;
SETFRAMEPARS_SET(P_COLOR_SATURATION_RED, csr);
}
cmprs_colorsat.colorsat_blue = csb;
cmprs_colorsat.colorsat_red = csr;
X393_SEQ_SEND1 (sensor_port, frame16, x393_cmprs_color_saturation, cmprs_colorsat);
MDF9(printk(" X393_SEQ_SEND1(0x%x, 0x%x, x393_cmprs_color_saturation, 0x%x)\n",sensor_port, frame16, cmprs_colorsat.d32));
}
// compressor quantizer zero bin mode changed?
// Quantizer tuning - bits 0..7 - zero bin, 15:8 - quantizer bias
if (FRAMEPAR_MODIFIED(P_CORING_PAGE)) {
cmprs_coring_mode.coring_table = thispars->pars[P_CORING_PAGE];
X393_SEQ_SEND1 (sensor_port, frame16, x393_cmprs_coring_mode, cmprs_coring_mode);
MDF9(printk(" X3X3_SEQ_SEND1(0x%x, 0x%x, x393_cmprs_coring_mode, 0x%x)\n", sensor_port, frame16, cmprs_coring_mode.d32));
}
if (nupdate) setFramePars(sensor_port, thispars, nupdate, pars_to_update); // save changes, schedule functions
#else
MDF3(printk(" frame16=%d\n",frame16)); MDF3(printk(" frame16=%d\n",frame16));
if (!jpeg_htable_is_programmed(sensor_port)) jpeg_htable_fpga_pgm (sensor_port); if (!jpeg_htable_is_programmed(sensor_port)) jpeg_htable_fpga_pgm (sensor_port);
if (frame16 >= PARS_FRAMES) return -1; // wrong frame if (frame16 >= PARS_FRAMES) return -1; // wrong frame
...@@ -1582,7 +1841,6 @@ int pgm_compmode (int sensor_port, ///< sensor port number (0..3 ...@@ -1582,7 +1841,6 @@ int pgm_compmode (int sensor_port, ///< sensor port number (0..3
} }
} }
// TODO: Redo for NC393 // TODO: Redo for NC393
#ifdef NC353
MDF3(printk("comp_cmd=0x%x\n",comp_cmd)); MDF3(printk("comp_cmd=0x%x\n",comp_cmd));
// Bayer shift changed? (additional bayer shift, separate from the gamma-tables one) // Bayer shift changed? (additional bayer shift, separate from the gamma-tables one)
if (FRAMEPAR_MODIFIED(P_COMPMOD_BYRSH)) { if (FRAMEPAR_MODIFIED(P_COMPMOD_BYRSH)) {
...@@ -1607,17 +1865,15 @@ int pgm_compmode (int sensor_port, ///< sensor port number (0..3 ...@@ -1607,17 +1865,15 @@ int pgm_compmode (int sensor_port, ///< sensor port number (0..3
// enqueue it for the compressor // enqueue it for the compressor
if (comp_cmd) { if (comp_cmd) {
#ifdef NC353
X3X3_SEQ_SEND1(fpga_addr, X313_WA_COMP_CMD, comp_cmd); X3X3_SEQ_SEND1(fpga_addr, X313_WA_COMP_CMD, comp_cmd);
#endif
MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", fpga_addr, (int) X313_WA_COMP_CMD, (int) comp_cmd)); MDF3(printk(" X3X3_SEQ_SEND1(0x%x,0x%x, 0x%x)\n", fpga_addr, (int) X313_WA_COMP_CMD, (int) comp_cmd));
} else { } else {
MDF3(printk(" comp_cmd==0, does not need to be sent\n")); MDF3(printk(" comp_cmd==0, does not need to be sent\n"));
} }
// color saturation changed? // color saturation changed?
if (FRAMEPAR_MODIFIED(P_COLOR_SATURATION_BLUE) || FRAMEPAR_MODIFIED(P_COLOR_SATURATION_RED)) { if (FRAMEPAR_MODIFIED(P_COLOR_SATURATION_BLUE) || FRAMEPAR_MODIFIED(P_COLOR_SATURATION_RED)) {
int csb=(thispars->pars[P_COLOR_SATURATION_BLUE]* DEFAULT_COLOR_SATURATION_BLUE)/100; csb=(thispars->pars[P_COLOR_SATURATION_BLUE]* DEFAULT_COLOR_SATURATION_BLUE)/100;
int csr=(thispars->pars[P_COLOR_SATURATION_RED] * DEFAULT_COLOR_SATURATION_RED)/100; csr=(thispars->pars[P_COLOR_SATURATION_RED] * DEFAULT_COLOR_SATURATION_RED)/100;
if (unlikely(csb>1023)) { if (unlikely(csb>1023)) {
csb=102300/DEFAULT_COLOR_SATURATION_BLUE; csb=102300/DEFAULT_COLOR_SATURATION_BLUE;
SETFRAMEPARS_SET(P_COLOR_SATURATION_BLUE, csb); SETFRAMEPARS_SET(P_COLOR_SATURATION_BLUE, csb);
...@@ -1626,10 +1882,8 @@ int pgm_compmode (int sensor_port, ///< sensor port number (0..3 ...@@ -1626,10 +1882,8 @@ int pgm_compmode (int sensor_port, ///< sensor port number (0..3
csr=102300/DEFAULT_COLOR_SATURATION_RED; csr=102300/DEFAULT_COLOR_SATURATION_RED;
SETFRAMEPARS_SET(P_COLOR_SATURATION_RED, csr); SETFRAMEPARS_SET(P_COLOR_SATURATION_RED, csr);
} }
#ifdef NC353
X3X3_SEQ_SEND1(fpga_addr, X313_WA_COLOR_SAT, ((DEFAULT_COLOR_SATURATION_BLUE*thispars->pars[P_COLOR_SATURATION_BLUE])/100) | X3X3_SEQ_SEND1(fpga_addr, X313_WA_COLOR_SAT, ((DEFAULT_COLOR_SATURATION_BLUE*thispars->pars[P_COLOR_SATURATION_BLUE])/100) |
(((DEFAULT_COLOR_SATURATION_RED *thispars->pars[P_COLOR_SATURATION_RED])/100)<<12)); (((DEFAULT_COLOR_SATURATION_RED *thispars->pars[P_COLOR_SATURATION_RED])/100)<<12));
#endif
MDF9(printk(" X3X3_SEQ_SEND1(0x%x, 0x%x, 0x%lx)\n", (int)fpga_addr, (int) X313_WA_COLOR_SAT, (int)((DEFAULT_COLOR_SATURATION_BLUE*thispars->pars[P_COLOR_SATURATION_BLUE])/100) | (((DEFAULT_COLOR_SATURATION_RED *thispars->pars[P_COLOR_SATURATION_RED])/100)<<12))); MDF9(printk(" X3X3_SEQ_SEND1(0x%x, 0x%x, 0x%lx)\n", (int)fpga_addr, (int) X313_WA_COLOR_SAT, (int)((DEFAULT_COLOR_SATURATION_BLUE*thispars->pars[P_COLOR_SATURATION_BLUE])/100) | (((DEFAULT_COLOR_SATURATION_RED *thispars->pars[P_COLOR_SATURATION_RED])/100)<<12)));
...@@ -1637,9 +1891,7 @@ int pgm_compmode (int sensor_port, ///< sensor port number (0..3 ...@@ -1637,9 +1891,7 @@ int pgm_compmode (int sensor_port, ///< sensor port number (0..3
// compressor quantizer zero bin mode changed? // compressor quantizer zero bin mode changed?
// Quantizer tuning - bits 0..7 - zero bin, 15:8 - quantizer bias // Quantizer tuning - bits 0..7 - zero bin, 15:8 - quantizer bias
if (FRAMEPAR_MODIFIED(P_CORING_PAGE)) { if (FRAMEPAR_MODIFIED(P_CORING_PAGE)) {
#ifdef NC353
X3X3_SEQ_SEND1(fpga_addr, X313_WA_QUANTIZER_MODE,thispars->pars[P_CORING_PAGE]); X3X3_SEQ_SEND1(fpga_addr, X313_WA_QUANTIZER_MODE,thispars->pars[P_CORING_PAGE]);
#endif
MDF9(printk(" X3X3_SEQ_SEND1(0x%x, 0x%x, 0x%x)\n", (int)fpga_addr, (int)X313_WA_QUANTIZER_MODE, (int)thispars->pars[P_CORING_PAGE])); MDF9(printk(" X3X3_SEQ_SEND1(0x%x, 0x%x, 0x%x)\n", (int)fpga_addr, (int)X313_WA_QUANTIZER_MODE, (int)thispars->pars[P_CORING_PAGE]));
} }
......
...@@ -6,6 +6,13 @@ ...@@ -6,6 +6,13 @@
int init_pgm_proc(void); int init_pgm_proc(void);
int add_sensor_proc(int index, int (*sens_func)(int sensor_port, struct sensor_t * , struct framepars_t * , struct framepars_t *, int )); int add_sensor_proc(int index, int (*sens_func)(int sensor_port, struct sensor_t * , struct framepars_t * , struct framepars_t *, int ));
/// Commands through sequencer: switch between ASAP (frame <0) and absolute
/// @param port - sensor port (0..3)
/// @param frame - <0 for ASAP command, otherwise absolute frame number to program for 4 LSB only are used)
/// @param func - part of the command write through sequencer w/o 'seqr_/seqa_ prefix
/// @param data - appropriate data type (matching function definition) to be written
#define X393_SEQ_SEND1(port,frame,func,data) {if ((frame) < 0) seqr_##func (0, (data), (port)); \
else seqa_##func ((frame), (data), (port)); }
/** Tells if parameter is modifies /** Tells if parameter is modifies
......
...@@ -16,172 +16,6 @@ ...@@ -16,172 +16,6 @@
*******************************************************************************/ *******************************************************************************/
#include "x393.h" #include "x393.h"
#include "x393_fpga_functions.h" #include "x393_fpga_functions.h"
/** Setup memory controller for a sensor channel */
int setup_sensor_memory (int num_sensor, ///< sensor port number (0..3)
int frame_sa, ///< 22-bit frame start address ((3 CA LSBs==0. BA==0)
int frame_sa_inc, ///< 22-bit frame start address increment ((3 CA LSBs==0. BA==0)
int last_frame_num, ///< 16-bit number of the last frame in a buffer
int frame_full_width, ///< 13-bit Padded line length (8-row increment), in 8-bursts (16 bytes)
int window_width, ///< 13-bit - in 8*16=128 bit bursts
int window_height, ///< 16-bit window height (in scan lines)
int window_left, ///< 13-bit window left margin in 8-bursts (16 bytes)
int window_top, ///< 16-bit window top margin (in scan lines
x393cmd_t x393cmd, ///< how to apply commands - directly or through channel sequencer
int frame16) ///< Frame number the command should be applied to (if not immediate mode)
///< @return 0 -OK
//typedef enum {DIRECT,ABSOLUTE,RELATIVE} x393cmd_t;
{
x393_mcntrl_mode_scan_t mcntrl_mode = {.enable = 1, // [ 0] (1) enable requests from this channel ( 0 will let current to finish, but not raise want/need)
.chn_nreset = 0, // [ 1] (1) 0: immediately reset all the internal circuitry
.write_mem = 1, // [ 2] (0) 0 - read from memory, 1 - write to memory
.extra_pages = 0, // [ 4: 3] (0) 2-bit number of extra pages that need to stay (not to be overwritten) in the buffer
.keep_open = 0, // [ 5] (0) (NA in linescan) for 8 or less rows - do not close page between accesses (not used in scanline mode)
.byte32 = 0, // [ 6] (1) (NA in linescan) 32-byte columns (0 - 16-byte), not used in scanline mode
.reset_frame = 0, // [ 8] (0) reset frame number
.single = 0, // [ 9] (0) run single frame
.repetitive = 1, // [ 10] (1) run repetitive frames
.disable_need = 0, // [ 11] (0) disable 'need' generation, only 'want' (compressor channels)
.skip_too_late = 1}; // [ 12] (0) Skip over missed blocks to preserve frame structure (increment pointers)
x393_mcntrl_window_frame_sa_t window_frame_sa = {.d32=0};
x393_mcntrl_window_frame_sa_inc_t window_frame_sa_inc = {.d32=0};
x393_mcntrl_window_last_frame_num_t window_last_frame_num = {.d32=0};
x393_mcntrl_window_full_width_t window_full_width = {.d32=0};
x393_mcntrl_window_width_height_t window_width_height = {.d32=0};
x393_mcntrl_window_left_top_t window_left_top = {.d32=0};
window_frame_sa.frame_sa = frame_sa;
window_frame_sa_inc.frame_sa_inc = frame_sa_inc;
window_last_frame_num.last_frame_num = last_frame_num;
window_full_width.full_width = frame_full_width;
window_width_height.width = window_width;
window_width_height.height = window_height;
window_left_top.left = window_left;
window_left_top.top = window_top;
switch (x393cmd){
case RELATIVE:
seqr_x393_sens_mcntrl_scanline_startaddr (frame16, window_frame_sa, num_sensor); // Set frame start address
seqr_x393_sens_mcntrl_scanline_frame_size (frame16, window_frame_sa_inc, num_sensor); // Set frame size (address increment)
seqr_x393_sens_mcntrl_scanline_frame_last (frame16, window_last_frame_num, num_sensor); // Set last frame number (number of frames in buffer minus 1)
seqr_x393_sens_mcntrl_scanline_frame_full_width (frame16, window_full_width, num_sensor); // Set frame full(padded) width
seqr_x393_sens_mcntrl_scanline_window_wh (frame16, window_width_height, num_sensor); // Set frame window size
seqr_x393_sens_mcntrl_scanline_window_x0y0 (frame16, window_left_top, num_sensor); // Set frame position
seqr_x393_sens_mcntrl_scanline_mode (frame16, mcntrl_mode, num_sensor); // Set mode register (write last after other channel registers are set)
break;
case ABSOLUTE:
seqa_x393_sens_mcntrl_scanline_startaddr (frame16, window_frame_sa, num_sensor); // Set frame start address
seqa_x393_sens_mcntrl_scanline_frame_size (frame16, window_frame_sa_inc, num_sensor); // Set frame size (address increment)
seqa_x393_sens_mcntrl_scanline_frame_last (frame16, window_last_frame_num, num_sensor); // Set last frame number (number of frames in buffer minus 1)
seqa_x393_sens_mcntrl_scanline_frame_full_width (frame16, window_full_width, num_sensor); // Set frame full(padded) width
seqa_x393_sens_mcntrl_scanline_window_wh (frame16, window_width_height, num_sensor); // Set frame window size
seqa_x393_sens_mcntrl_scanline_window_x0y0 (frame16, window_left_top, num_sensor); // Set frame position
seqa_x393_sens_mcntrl_scanline_mode (frame16, mcntrl_mode, num_sensor); // Set mode register (write last after other channel registers are set)
break;
case DIRECT:
x393_sens_mcntrl_scanline_startaddr (window_frame_sa, num_sensor); // Set frame start address
x393_sens_mcntrl_scanline_frame_size (window_frame_sa_inc, num_sensor); // Set frame size (address increment)
x393_sens_mcntrl_scanline_frame_last (window_last_frame_num, num_sensor); // Set last frame number (number of frames in buffer minus 1)
x393_sens_mcntrl_scanline_frame_full_width (window_full_width, num_sensor); // Set frame full(padded) width
x393_sens_mcntrl_scanline_window_wh (window_width_height, num_sensor); // Set frame window size
x393_sens_mcntrl_scanline_window_x0y0 (window_left_top, num_sensor); // Set frame position
x393_sens_mcntrl_scanline_mode (mcntrl_mode, num_sensor); // Set mode register (write last after other channel registers are set)
break;
}
return 0;
}
/** Setup memory controller for a compressor channel */
int setup_compressor_memory (int num_sensor, ///< sensor port number (0..3)
int frame_sa, ///< 22-bit frame start address ((3 CA LSBs==0. BA==0)
int frame_sa_inc, ///< 22-bit frame start address increment ((3 CA LSBs==0. BA==0)
int last_frame_num, ///< 16-bit number of the last frame in a buffer
int frame_full_width, ///< 13-bit Padded line length (8-row increment), in 8-bursts (16 bytes)
int window_width, ///< 13-bit - in 8*16=128 bit bursts
int window_height, ///< 16-bit window height (in scan lines)
int window_left, ///< 13-bit window left margin in 8-bursts (16 bytes)
int window_top, ///< 16-bit window top margin (in scan lines
int byte32, ///< 1 - 32-byte columns (currently used), 0 - 16 byte columns
int tile_width, ///< tile width in pixels
int tile_vstep, ///< tile vertical step in pixel rows (JPEG18/jp4 = 16) // = 16
int tile_height, ///< tile height: 18 for color JPEG, 16 for JP4 flavors // = 18
int extra_pages, ///< extra pages needed (1) - number of previous pages to keep in a 4-page buffer
int disable_need, ///< disable "need" (yield to sensor channels - they can not wait)
x393cmd_t x393cmd, ///< how to apply commands - directly or through channel sequencer
int frame16) ///< Frame number the command should be applied to (if not immediate mode)
///< @return 0 - OK
{
x393_mcntrl_mode_scan_t mcntrl_mode = {.enable = 1, // [ 0] (1) enable requests from this channel ( 0 will let current to finish, but not raise want/need)
.chn_nreset = 0, // [ 1] (1) 0: immediately reset all the internal circuitry
.write_mem = 0, // [ 2] (0) 0 - read from memory, 1 - write to memory
.extra_pages = 1, // [ 4: 3] (0) 2-bit number of extra pages that need to stay (not to be overwritten) in the buffer
.keep_open = 0, // [ 5] (0) (NA in linescan) for 8 or less rows - do not close page between accesses (not used in scanline mode)
.byte32 = 1, // [ 6] (1) (NA in linescan) 32-byte columns (0 - 16-byte), not used in scanline mode
.reset_frame = 0, // [ 8] (0) reset frame number
.single = 0, // [ 9] (0) run single frame
.repetitive = 1, // [ 10] (1) run repetitive frames
.disable_need = 1, // [ 11] (0) disable 'need' generation, only 'want' (compressor channels)
.skip_too_late = 1};// [ 12] (0) Skip over missed blocks to preserve frame structure (increment pointers)
x393_mcntrl_window_frame_sa_t window_frame_sa = {.d32=0};
x393_mcntrl_window_frame_sa_inc_t window_frame_sa_inc = {.d32=0};
x393_mcntrl_window_last_frame_num_t window_last_frame_num = {.d32=0};
x393_mcntrl_window_full_width_t window_full_width = {.d32=0};
x393_mcntrl_window_width_height_t window_width_height = {.d32=0};
x393_mcntrl_window_left_top_t window_left_top = {.d32=0};
x393_mcntrl_window_tile_whs_t window_tile_whs = {.d32=0};
window_frame_sa.frame_sa = frame_sa;
window_frame_sa_inc.frame_sa_inc = frame_sa_inc;
window_last_frame_num.last_frame_num = last_frame_num;
window_full_width.full_width = frame_full_width;
window_width_height.width = window_width;
window_width_height.height = window_height;
window_left_top.left = window_left;
window_left_top.top = window_top;
window_tile_whs.tile_width = tile_width;
window_tile_whs.vert_step = tile_vstep;
window_tile_whs.tile_height = tile_height;
mcntrl_mode.disable_need = disable_need; // non-constant parameter
mcntrl_mode.extra_pages = extra_pages; // non-constant parameter
switch (x393cmd){
case RELATIVE:
seqr_x393_sens_mcntrl_tiled_startaddr (frame16, window_frame_sa, num_sensor); // Set frame start address
seqr_x393_sens_mcntrl_tiled_frame_size (frame16, window_frame_sa_inc, num_sensor); // Set frame size (address increment)
seqr_x393_sens_mcntrl_tiled_frame_last (frame16, window_last_frame_num, num_sensor); // Set last frame number (number of frames in buffer minus 1)
seqr_x393_sens_mcntrl_tiled_frame_full_width (frame16, window_full_width, num_sensor); // Set frame full(padded) width
seqr_x393_sens_mcntrl_tiled_window_wh (frame16, window_width_height, num_sensor); // Set frame window size
seqr_x393_sens_mcntrl_tiled_window_x0y0 (frame16, window_left_top, num_sensor); // Set frame position
seqr_x393_sens_mcntrl_tiled_tile_whs (frame16, window_tile_whs, num_sensor); // Set tile size/step (tiled mode only)
seqr_x393_sens_mcntrl_tiled_mode (frame16, mcntrl_mode, num_sensor); // Set mode register (write last after other channel registers are set)
break;
case ABSOLUTE:
seqa_x393_sens_mcntrl_tiled_startaddr (frame16, window_frame_sa, num_sensor); // Set frame start address
seqa_x393_sens_mcntrl_tiled_frame_size (frame16, window_frame_sa_inc, num_sensor); // Set frame size (address increment)
seqa_x393_sens_mcntrl_tiled_frame_last (frame16, window_last_frame_num, num_sensor); // Set last frame number (number of frames in buffer minus 1)
seqa_x393_sens_mcntrl_tiled_frame_full_width (frame16, window_full_width, num_sensor); // Set frame full(padded) width
seqa_x393_sens_mcntrl_tiled_window_wh (frame16, window_width_height, num_sensor); // Set frame window size
seqa_x393_sens_mcntrl_tiled_window_x0y0 (frame16, window_left_top, num_sensor); // Set frame position
seqa_x393_sens_mcntrl_tiled_tile_whs (frame16, window_tile_whs, num_sensor); // Set tile size/step (tiled mode only)
seqa_x393_sens_mcntrl_tiled_mode (frame16, mcntrl_mode, num_sensor); // Set mode register (write last after other channel registers are set)
break;
case DIRECT:
x393_sens_mcntrl_tiled_startaddr (window_frame_sa, num_sensor); // Set frame start address
x393_sens_mcntrl_tiled_frame_size (window_frame_sa_inc, num_sensor); // Set frame size (address increment)
x393_sens_mcntrl_tiled_frame_last (window_last_frame_num, num_sensor); // Set last frame number (number of frames in buffer minus 1)
x393_sens_mcntrl_tiled_frame_full_width (window_full_width, num_sensor); // Set frame full(padded) width
x393_sens_mcntrl_tiled_window_wh (window_width_height, num_sensor); // Set frame window size
x393_sens_mcntrl_tiled_window_x0y0 (window_left_top, num_sensor); // Set frame position
x393_sens_mcntrl_tiled_tile_whs (window_tile_whs, num_sensor); // Set tile size/step (tiled mode only)
x393_sens_mcntrl_tiled_mode (mcntrl_mode, num_sensor); // Set mode register (write last after other channel registers are set)
break;
}
return 0;
}
/* /*
......
...@@ -16,8 +16,3 @@ ...@@ -16,8 +16,3 @@
*******************************************************************************/ *******************************************************************************/
//typedef enum {DIRECT,ABSOLUTE,RELATIVE} x393cmd_t; //typedef enum {DIRECT,ABSOLUTE,RELATIVE} x393cmd_t;
#include "x393.h" #include "x393.h"
int setup_sensor_memory (int num_sensor, int frame_sa, int frame_sa_inc, int last_frame_num, int frame_full_width,
int window_width, int window_height, int window_left, int window_top, x393cmd_t x393cmd, int frame16);
int setup_compressor_memory (int num_sensor, int frame_sa, int frame_sa_inc, int last_frame_num, int frame_full_width,
int window_width, int window_height, int window_left, int window_top, int byte32, int tile_width, int tile_vstep,
int tile_height, int extra_pages, int disable_need, x393cmd_t x393cmd, int frame16);
...@@ -91,6 +91,9 @@ int setup_sensor_memory (int num_sensor, ///< sensor port number (0..3) ...@@ -91,6 +91,9 @@ int setup_sensor_memory (int num_sensor, ///< sensor port number (0..3)
window_left_top.top = window_top; window_left_top.top = window_top;
switch (x393cmd){ switch (x393cmd){
case ASAP:
frame16 = 0;
// no break
case RELATIVE: case RELATIVE:
seqr_x393_sens_mcntrl_scanline_startaddr (frame16, window_frame_sa, num_sensor); // Set frame start address seqr_x393_sens_mcntrl_scanline_startaddr (frame16, window_frame_sa, num_sensor); // Set frame start address
seqr_x393_sens_mcntrl_scanline_frame_size (frame16, window_frame_sa_inc, num_sensor); // Set frame size (address increment) seqr_x393_sens_mcntrl_scanline_frame_size (frame16, window_frame_sa_inc, num_sensor); // Set frame size (address increment)
...@@ -129,8 +132,10 @@ int setup_compressor_memory (int num_sensor, ///< sensor port number (0..3 ...@@ -129,8 +132,10 @@ int setup_compressor_memory (int num_sensor, ///< sensor port number (0..3
int window_height, ///< 16-bit window height (in scan lines) int window_height, ///< 16-bit window height (in scan lines)
int window_left, ///< 13-bit window left margin in 8-bursts (16 bytes) int window_left, ///< 13-bit window left margin in 8-bursts (16 bytes)
int window_top, ///< 16-bit window top margin (in scan lines int window_top, ///< 16-bit window top margin (in scan lines
int tile_width, ///< tile width in pixels int tile_width, ///< tile width in bjursts (16-pixels each)
int tile_height, ///< tile height: 18 for color JPEG, 16 for JP4 flavors // = 18 int tile_height, ///< tile height: 18 for color JPEG, 16 for JP4 flavors // = 18
int tile_vstep, ///< tile vertical step in pixel rows (JPEG18/jp4 = 16) // = 16
int extra_pages, ///< extra pages needed (1) - number of previous pages to keep in a 4-page buffer
int disable_need, ///< disable "need" (yield to sensor channels - they can not wait) int disable_need, ///< disable "need" (yield to sensor channels - they can not wait)
x393cmd_t x393cmd, ///< how to apply commands - directly or through channel sequencer x393cmd_t x393cmd, ///< how to apply commands - directly or through channel sequencer
int frame16) ///< Frame number the command should be applied to (if not immediate mode) int frame16) ///< Frame number the command should be applied to (if not immediate mode)
...@@ -141,8 +146,6 @@ int setup_compressor_memory (int num_sensor, ///< sensor port number (0..3 ...@@ -141,8 +146,6 @@ int setup_compressor_memory (int num_sensor, ///< sensor port number (0..3
int frame_sa_inc = frame_full_width * (buffer_settings.frame_height[num_sensor] >>3); int frame_sa_inc = frame_full_width * (buffer_settings.frame_height[num_sensor] >>3);
int last_frame_num = buffer_settings.frames_in_buffer[num_sensor] - 1; int last_frame_num = buffer_settings.frames_in_buffer[num_sensor] - 1;
int byte32 = 1; ///< 1 - 32-byte columns (currently used), 0 - 16 byte columns int byte32 = 1; ///< 1 - 32-byte columns (currently used), 0 - 16 byte columns
int tile_vstep = 16; ///< tile vertical step in pixel rows (JPEG18/jp4 = 16) // = 16
int extra_pages = 1; ///< extra pages needed (1) - number of previous pages to keep in a 4-page buffer
x393_mcntrl_mode_scan_t mcntrl_mode = {.enable = 1, // [ 0] (1) enable requests from this channel ( 0 will let current to finish, but not raise want/need) x393_mcntrl_mode_scan_t mcntrl_mode = {.enable = 1, // [ 0] (1) enable requests from this channel ( 0 will let current to finish, but not raise want/need)
.chn_nreset = 0, // [ 1] (1) 0: immediately reset all the internal circuitry .chn_nreset = 0, // [ 1] (1) 0: immediately reset all the internal circuitry
...@@ -179,6 +182,9 @@ int setup_compressor_memory (int num_sensor, ///< sensor port number (0..3 ...@@ -179,6 +182,9 @@ int setup_compressor_memory (int num_sensor, ///< sensor port number (0..3
mcntrl_mode.extra_pages = extra_pages; // non-constant parameter mcntrl_mode.extra_pages = extra_pages; // non-constant parameter
switch (x393cmd){ switch (x393cmd){
case ASAP:
frame16 = 0;
// no break
case RELATIVE: case RELATIVE:
seqr_x393_sens_mcntrl_tiled_startaddr (frame16, window_frame_sa, num_sensor); // Set frame start address seqr_x393_sens_mcntrl_tiled_startaddr (frame16, window_frame_sa, num_sensor); // Set frame start address
seqr_x393_sens_mcntrl_tiled_frame_size (frame16, window_frame_sa_inc, num_sensor); // Set frame size (address increment) seqr_x393_sens_mcntrl_tiled_frame_size (frame16, window_frame_sa_inc, num_sensor); // Set frame size (address increment)
......
...@@ -23,3 +23,9 @@ struct elphel_video_buf_t ...@@ -23,3 +23,9 @@ struct elphel_video_buf_t
int frames_in_buffer[4]; ///< Number of frames in channel 0 buffer int frames_in_buffer[4]; ///< Number of frames in channel 0 buffer
}; };
int setup_sensor_memory (int num_sensor, int window_width, int window_height, int window_left,
int window_top, x393cmd_t x393cmd, int frame16);
int setup_compressor_memory (int num_sensor, int window_width, int window_height, int window_left,
int window_top, int tile_width, int tile_height, int tile_vstep,
int extra_pages, int disable_need, x393cmd_t x393cmd, int frame16);
...@@ -293,10 +293,10 @@ ...@@ -293,10 +293,10 @@
<li> bit 2 - async (snapshot, ext trigger) mode, 0 - continuous NOTE: Only this bit is used now <li> bit 2 - async (snapshot, ext trigger) mode, 0 - continuous NOTE: Only this bit is used now
<li> bit 3 - no overlap, single frames: program - acquire/compress same frame</ul>*/ <li> bit 3 - no overlap, single frames: program - acquire/compress same frame</ul>*/
#define P_BGFRAME 16 ///< Background measurement mode - will use 16-bit mode and no FPN correction #define P_BGFRAME 16 ///< Background measurement mode - will use 16-bit mode and no FPN correction
#define P_IMGSZMEM 17 ///< image size in video memory (calculated when channel 0 is programmed) #define P_IMGSZMEM 17 ///< image size in video memory (calculated when channel 0 is programmed) NC393: Not used ???
// image page numbers depend on image size/pixel depth, so changing any of them will invalidate all pages // image page numbers depend on image size/pixel depth, so changing any of them will invalidate all pages
#define P_PAGE_ACQ 18 ///< Number of image page buffer to acquire to (0.1?) #define P_PAGE_ACQ 18 ///< Number of image page buffer to acquire to (0.1?) NC393: Not used ???
#define P_PAGE_READ 19 ///< Number of image page buffer to read from to (0.1?) #define P_PAGE_READ 19 ///< Number of image page buffer to read from to (0.1?) NC393: Not used ???
#define P_OVERLAP 20 ///< number of EXRA lines to be acquired - probably dead, #define P_OVERLAP 20 ///< number of EXRA lines to be acquired - probably dead,
#define P_VIRT_KEEP 21 ///< 0 - recalculate P_VIRT_WIDTH, P_VIRT_HEIGHT when window is changed, 1 - keep those parameters #define P_VIRT_KEEP 21 ///< 0 - recalculate P_VIRT_WIDTH, P_VIRT_HEIGHT when window is changed, 1 - keep those parameters
#define P_VIRT_WIDTH 22 ///< Virtual window width #define P_VIRT_WIDTH 22 ///< Virtual window width
...@@ -312,7 +312,8 @@ ...@@ -312,7 +312,8 @@
#define P_BIN_HOR 32 ///< binning 1/2 - KAC1310 only - now for mt9t001 #define P_BIN_HOR 32 ///< binning 1/2 - KAC1310 only - now for mt9t001
#define P_BIN_VERT 33 ///< not used yet binning 1/2 - KAC1310 only - now for mt9t001 #define P_BIN_VERT 33 ///< not used yet binning 1/2 - KAC1310 only - now for mt9t001
#define P_FPGATEST 34 ///< FPGA test modes (now - just one) #define P_FPGATEST 34 ///< FPGA test modes (now - just one)
#define P_FRAMESYNC_DLY 35 ///< maybe - temporary - delay of frame sync (vacts) by number of scan lines - for photofinish mode #define P_FRAMESYNC_DLY 35 ///< maybe - temporary - delay of frame sync (vacts) by number of scan lines - for photofinish mode // not used anywhere?
///< Lower bits 16 will be used to delay frame sync, bit 16 - use internal HACT duration (0 - use from sensor) [*]
#define P_PF_HEIGHT 36 ///< height of each strip in photofinish mode - normally 2 lines #define P_PF_HEIGHT 36 ///< height of each strip in photofinish mode - normally 2 lines
///< also now includes timestamping mode +0x10000 - for normal frames, 0x20000 - for photo-finish ///< also now includes timestamping mode +0x10000 - for normal frames, 0x20000 - for photo-finish
#define P_BITS 37 ///< pixel depth - bits 10/8/4 #define P_BITS 37 ///< pixel depth - bits 10/8/4
...@@ -331,7 +332,7 @@ ...@@ -331,7 +332,7 @@
#define P_SENSOR_PIXV 46 ///< (readonly) pixels to be read from the sensor, vertical (including margins) #define P_SENSOR_PIXV 46 ///< (readonly) pixels to be read from the sensor, vertical (including margins)
#define P_FATZERO 47 ///< subtract while adding data from to consecutive frames (async trigger) #define P_FATZERO 47 ///< subtract while adding data from to consecutive frames (async trigger)
#define P_COMPMOD_TILSH 48 ///< Horizontal tiles - obsolete in 393? #define P_COMPMOD_TILSH 48 ///< Horizontal tiles - obsolete in 393? YES
#define P_COMPMOD_DCSUB 49 ///< Subtract DC in compressor before DCT #define P_COMPMOD_DCSUB 49 ///< Subtract DC in compressor before DCT
#define P_COMPMOD_QTAB 50 ///< to be written not directly, but by pgm_quality ? #define P_COMPMOD_QTAB 50 ///< to be written not directly, but by pgm_quality ?
...@@ -459,8 +460,8 @@ ...@@ -459,8 +460,8 @@
// 393: Are they the same? // 393: Are they the same?
#define P_COLOR 135 ///< mono - 0, color mode - 1, +0 - normal, 256 - sensor test, 512 - FPGA test #define P_COLOR 135 ///< mono - 0, color mode - 1, +0 - normal, 256 - sensor test, 512 - FPGA test
#define COLORMODE_MONO6 0 ///< monochrome, (4:2:0), #define COLORMODE_MONO6 1 ///< monochrome, (4:2:0), was:0
#define COLORMODE_COLOR 1 ///< color, 4:2:0, 18x18(old) #define COLORMODE_COLOR 0 ///< color, 4:2:0, 18x18(old) was: 1
#define COLORMODE_JP46 2 ///< jp4, original (4:2:0) #define COLORMODE_JP46 2 ///< jp4, original (4:2:0)
#define COLORMODE_JP46DC 3 ///< jp4, dc -improved (4:2:0) #define COLORMODE_JP46DC 3 ///< jp4, dc -improved (4:2:0)
#define COLORMODE_COLOR20 4 ///< color, 4:2:0, 20x20, middle of the tile (not yet implemented) #define COLORMODE_COLOR20 4 ///< color, 4:2:0, 20x20, middle of the tile (not yet implemented)
...@@ -1662,8 +1663,8 @@ struct sensorproc_t { ...@@ -1662,8 +1663,8 @@ struct sensorproc_t {
*! that goes after the encoded frame, so total is 36 bytes (26+2+8) *! that goes after the encoded frame, so total is 36 bytes (26+2+8)
!****************************************************************************************************/ !****************************************************************************************************/
// move fram x353.h // move fram x353.h
#define DEFAULT_COLOR_SATURATION_BLUE 0x90 ///< 100*realtive saturation blue #define DEFAULT_COLOR_SATURATION_BLUE 0x90 ///< 100*relative saturation blue
#define DEFAULT_COLOR_SATURATION_RED 0xb6 ///< 100*realtive saturation red #define DEFAULT_COLOR_SATURATION_RED 0xb6 ///< 100*relative saturation red
//#define EXPOSURE_UNIT 100 // to move to finer exposure settings - current unit in microseconds. TODO: Propagate it to drivers... //#define EXPOSURE_UNIT 100 // to move to finer exposure settings - current unit in microseconds. TODO: Propagate it to drivers...
#define EXPOSURE_UNIT 1 ///< to move to finer exposure settings - current unit in microseconds. TODO: Propagate it to drivers... #define EXPOSURE_UNIT 1 ///< to move to finer exposure settings - current unit in microseconds. TODO: Propagate it to drivers...
......
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