/* Matrox MGA driver ported to VIDIX by Alex Beregszaszi YUY2 support (see config.format) added by A'rpi/ESP-team double buffering added by A'rpi/ESP-team */ /* * Original copyright: * * mga_vid.c * * Copyright (C) 1999 Aaron Holtzman * * Module skeleton based on gutted agpgart module by Jeff Hartmann * <slicer@ionet.net> * * Matrox MGA G200/G400 YUV Video Interface module Version 0.1.0 * * BES == Back End Scaler * * This software has been released under the terms of the GNU Public * license. See http://www.gnu.org/copyleft/gpl.html for details. */ //#define CRTC2 // Set this value, if autodetection fails! (video ram size in megabytes) // #define MGA_MEMORY_SIZE 16 /* disable irq */ #undef MGA_ALLOW_IRQ #define MGA_VSYNC_POS 2 #include <errno.h> #include <stdio.h> #include <stdlib.h> #include <string.h> #include <math.h> #include <inttypes.h> #include "../vidix.h" #include "../fourcc.h" #include "../../libdha/libdha.h" #include "../../libdha/pci_ids.h" #include "../../libdha/pci_names.h" #if !defined(ENOTSUP) && defined(EOPNOTSUPP) #define ENOTSUP EOPNOTSUPP #endif /* from radeon_vid */ #define GETREG(TYPE,PTR,OFFZ) (*((volatile TYPE*)((PTR)+(OFFZ)))) #define SETREG(TYPE,PTR,OFFZ,VAL) (*((volatile TYPE*)((PTR)+(OFFZ))))=VAL #define readb(addr) GETREG(uint8_t,(uint32_t)(addr),0) #define writeb(val,addr) SETREG(uint8_t,(uint32_t)(addr),0,val) #define readl(addr) GETREG(uint32_t,(uint32_t)(addr),0) #define writel(val,addr) SETREG(uint32_t,(uint32_t)(addr),0,val) int mga_verbose = 0; /* for device detection */ static int probed = 0; static pciinfo_t pci_info; /* internal booleans */ static uint32_t mga_vid_in_use = 0; static uint32_t is_g400 = 0; static uint32_t vid_src_ready = 0; static uint32_t vid_overlay_on = 0; /* mapped physical addresses */ static uint8_t *mga_mmio_base = 0; static uint32_t mga_mem_base = 0; static int mga_src_base = 0; /* YUV buffer position in video memory */ static uint32_t mga_ram_size = 0; /* how much megabytes videoram we have */ /* Graphic keys */ static vidix_grkey_t mga_grkey; static int colkey_saved=0; static int colkey_on=0; static unsigned char colkey_color[4]; static unsigned char colkey_mask[4]; /* for IRQ */ static int mga_irq = -1; static int mga_next_frame = 0; static vidix_capability_t mga_cap = { "Matrox MGA G200/G400 YUV Video", TYPE_OUTPUT, { 0, 0, 0, 0 }, 1024, /* 2048x2048 is supported if Pontscho is right */ 768, 4, 4, -1, FLAG_UPSCALER | FLAG_DOWNSCALER, VENDOR_MATROX, 0, { 0, 0, 0, 0} }; /* MATROX BES registers */ typedef struct bes_registers_s { //BES Control uint32_t besctl; //BES Global control uint32_t besglobctl; //Luma control (brightness and contrast) uint32_t beslumactl; //Line pitch uint32_t bespitch; //Buffer A-1 Chroma 3 plane org uint32_t besa1c3org; //Buffer A-1 Chroma org uint32_t besa1corg; //Buffer A-1 Luma org uint32_t besa1org; //Buffer A-2 Chroma 3 plane org uint32_t besa2c3org; //Buffer A-2 Chroma org uint32_t besa2corg; //Buffer A-2 Luma org uint32_t besa2org; //Buffer B-1 Chroma 3 plane org uint32_t besb1c3org; //Buffer B-1 Chroma org uint32_t besb1corg; //Buffer B-1 Luma org uint32_t besb1org; //Buffer B-2 Chroma 3 plane org uint32_t besb2c3org; //Buffer B-2 Chroma org uint32_t besb2corg; //Buffer B-2 Luma org uint32_t besb2org; //BES Horizontal coord uint32_t beshcoord; //BES Horizontal inverse scaling [5.14] uint32_t beshiscal; //BES Horizontal source start [10.14] (for scaling) uint32_t beshsrcst; //BES Horizontal source ending [10.14] (for scaling) uint32_t beshsrcend; //BES Horizontal source last uint32_t beshsrclst; //BES Vertical coord uint32_t besvcoord; //BES Vertical inverse scaling [5.14] uint32_t besviscal; //BES Field 1 vertical source last position uint32_t besv1srclst; //BES Field 1 weight start uint32_t besv1wght; //BES Field 2 vertical source last position uint32_t besv2srclst; //BES Field 2 weight start uint32_t besv2wght; } bes_registers_t; static bes_registers_t regs; #ifdef CRTC2 typedef struct crtc2_registers_s { uint32_t c2ctl; uint32_t c2datactl; uint32_t c2misc; uint32_t c2hparam; uint32_t c2hsync; uint32_t c2offset; uint32_t c2pl2startadd0; uint32_t c2pl2startadd1; uint32_t c2pl3startadd0; uint32_t c2pl3startadd1; uint32_t c2preload; uint32_t c2spicstartadd0; uint32_t c2spicstartadd1; uint32_t c2startadd0; uint32_t c2startadd1; uint32_t c2subpiclut; uint32_t c2vcount; uint32_t c2vparam; uint32_t c2vsync; } crtc2_registers_t; static crtc2_registers_t cregs; #endif //All register offsets are converted to word aligned offsets (32 bit) //because we want all our register accesses to be 32 bits #define VCOUNT 0x1e20 #define PALWTADD 0x3c00 // Index register for X_DATAREG port #define X_DATAREG 0x3c0a #define XMULCTRL 0x19 #define BPP_8 0x00 #define BPP_15 0x01 #define BPP_16 0x02 #define BPP_24 0x03 #define BPP_32_DIR 0x04 #define BPP_32_PAL 0x07 #define XCOLMSK 0x40 #define X_COLKEY 0x42 #define XKEYOPMODE 0x51 #define XCOLMSK0RED 0x52 #define XCOLMSK0GREEN 0x53 #define XCOLMSK0BLUE 0x54 #define XCOLKEY0RED 0x55 #define XCOLKEY0GREEN 0x56 #define XCOLKEY0BLUE 0x57 #ifdef CRTC2 /*CRTC2 registers*/ #define XMISCCTRL 0x1e #define C2CTL 0x3c10 #define C2DATACTL 0x3c4c #define C2MISC 0x3c44 #define C2HPARAM 0x3c14 #define C2HSYNC 0x3c18 #define C2OFFSET 0x3c40 #define C2PL2STARTADD0 0x3c30 // like BESA1CORG #define C2PL2STARTADD1 0x3c34 // like BESA2CORG #define C2PL3STARTADD0 0x3c38 // like BESA1C3ORG #define C2PL3STARTADD1 0x3c3c // like BESA2C3ORG #define C2PRELOAD 0x3c24 #define C2SPICSTARTADD0 0x3c54 #define C2SPICSTARTADD1 0x3c58 #define C2STARTADD0 0x3c28 // like BESA1ORG #define C2STARTADD1 0x3c2c // like BESA2ORG #define C2SUBPICLUT 0x3c50 #define C2VCOUNT 0x3c48 #define C2VPARAM 0x3c1c #define C2VSYNC 0x3c20 #endif // Backend Scaler registers #define BESCTL 0x3d20 #define BESGLOBCTL 0x3dc0 #define BESLUMACTL 0x3d40 #define BESPITCH 0x3d24 #define BESA1C3ORG 0x3d60 #define BESA1CORG 0x3d10 #define BESA1ORG 0x3d00 #define BESA2C3ORG 0x3d64 #define BESA2CORG 0x3d14 #define BESA2ORG 0x3d04 #define BESB1C3ORG 0x3d68 #define BESB1CORG 0x3d18 #define BESB1ORG 0x3d08 #define BESB2C3ORG 0x3d6C #define BESB2CORG 0x3d1C #define BESB2ORG 0x3d0C #define BESHCOORD 0x3d28 #define BESHISCAL 0x3d30 #define BESHSRCEND 0x3d3C #define BESHSRCLST 0x3d50 #define BESHSRCST 0x3d38 #define BESV1WGHT 0x3d48 #define BESV2WGHT 0x3d4c #define BESV1SRCLST 0x3d54 #define BESV2SRCLST 0x3d58 #define BESVISCAL 0x3d34 #define BESVCOORD 0x3d2c #define BESSTATUS 0x3dc4 #define CRTCX 0x1fd4 #define CRTCD 0x1fd5 #define IEN 0x1e1c #define ICLEAR 0x1e18 #define STATUS 0x1e14 #ifdef CRTC2 static void crtc2_frame_sel(int frame) { switch(frame) { case 0: cregs.c2pl2startadd0=regs.besa1corg; cregs.c2pl3startadd0=regs.besa1c3org; cregs.c2startadd0=regs.besa1org; break; case 1: cregs.c2pl2startadd0=regs.besa2corg; cregs.c2pl3startadd0=regs.besa2c3org; cregs.c2startadd0=regs.besa2org; break; case 2: cregs.c2pl2startadd0=regs.besb1corg; cregs.c2pl3startadd0=regs.besb1c3org; cregs.c2startadd0=regs.besb1org; break; case 3: cregs.c2pl2startadd0=regs.besb2corg; cregs.c2pl3startadd0=regs.besb2c3org; cregs.c2startadd0=regs.besb2org; break; } writel(cregs.c2startadd0, mga_mmio_base + C2STARTADD0); writel(cregs.c2pl2startadd0, mga_mmio_base + C2PL2STARTADD0); writel(cregs.c2pl3startadd0, mga_mmio_base + C2PL3STARTADD0); } #endif int vixPlaybackFrameSelect(unsigned int frame) { #if MGA_ALLOW_IRQ if (mga_irq != -1) { mga_next_frame = frame; } else #endif { //we don't need the vcount protection as we're only hitting //one register (and it doesn't seem to be double buffered) regs.besctl = (regs.besctl & ~0x07000000) + (frame << 25); writel( regs.besctl, mga_mmio_base + BESCTL ); // writel( regs.besglobctl + ((readl(mga_mmio_base + VCOUNT)+2)<<16), writel( regs.besglobctl + (MGA_VSYNC_POS<<16), mga_mmio_base + BESGLOBCTL); #ifdef CRTC2 crtc2_frame_sel(frame); #endif } return(0); } static void mga_vid_write_regs(int restore) { //Make sure internal registers don't get updated until we're done writel( (readl(mga_mmio_base + VCOUNT)-1)<<16, mga_mmio_base + BESGLOBCTL); // color or coordinate keying if(restore && colkey_saved){ // restore it colkey_saved=0; printf("[mga] Restoring colorkey (ON: %d %02X:%02X:%02X)\n", colkey_on,colkey_color[0],colkey_color[1],colkey_color[2]); // Set color key registers: writeb( XKEYOPMODE, mga_mmio_base + PALWTADD); writeb( colkey_on, mga_mmio_base + X_DATAREG); writeb( XCOLKEY0RED, mga_mmio_base + PALWTADD); writeb( colkey_color[0], mga_mmio_base + X_DATAREG); writeb( XCOLKEY0GREEN, mga_mmio_base + PALWTADD); writeb( colkey_color[1], mga_mmio_base + X_DATAREG); writeb( XCOLKEY0BLUE, mga_mmio_base + PALWTADD); writeb( colkey_color[2], mga_mmio_base + X_DATAREG); writeb( X_COLKEY, mga_mmio_base + PALWTADD); writeb( colkey_color[3], mga_mmio_base + X_DATAREG); writeb( XCOLMSK0RED, mga_mmio_base + PALWTADD); writeb( colkey_mask[0], mga_mmio_base + X_DATAREG); writeb( XCOLMSK0GREEN, mga_mmio_base + PALWTADD); writeb( colkey_mask[1], mga_mmio_base + X_DATAREG); writeb( XCOLMSK0BLUE, mga_mmio_base + PALWTADD); writeb( colkey_mask[2], mga_mmio_base + X_DATAREG); writeb( XCOLMSK, mga_mmio_base + PALWTADD); writeb( colkey_mask[3], mga_mmio_base + X_DATAREG); } else if(!colkey_saved){ // save it colkey_saved=1; // Get color key registers: writeb( XKEYOPMODE, mga_mmio_base + PALWTADD); colkey_on=(unsigned char)readb(mga_mmio_base + X_DATAREG) & 1; writeb( XCOLKEY0RED, mga_mmio_base + PALWTADD); colkey_color[0]=(unsigned char)readb(mga_mmio_base + X_DATAREG); writeb( XCOLKEY0GREEN, mga_mmio_base + PALWTADD); colkey_color[1]=(unsigned char)readb(mga_mmio_base + X_DATAREG); writeb( XCOLKEY0BLUE, mga_mmio_base + PALWTADD); colkey_color[2]=(unsigned char)readb(mga_mmio_base + X_DATAREG); writeb( X_COLKEY, mga_mmio_base + PALWTADD); colkey_color[3]=(unsigned char)readb(mga_mmio_base + X_DATAREG); writeb( XCOLMSK0RED, mga_mmio_base + PALWTADD); colkey_mask[0]=(unsigned char)readb(mga_mmio_base + X_DATAREG); writeb( XCOLMSK0GREEN, mga_mmio_base + PALWTADD); colkey_mask[1]=(unsigned char)readb(mga_mmio_base + X_DATAREG); writeb( XCOLMSK0BLUE, mga_mmio_base + PALWTADD); colkey_mask[2]=(unsigned char)readb(mga_mmio_base + X_DATAREG); writeb( XCOLMSK, mga_mmio_base + PALWTADD); colkey_mask[3]=(unsigned char)readb(mga_mmio_base + X_DATAREG); printf("[mga] Saved colorkey (ON: %d %02X:%02X:%02X)\n", colkey_on,colkey_color[0],colkey_color[1],colkey_color[2]); } if(!restore){ writeb( XKEYOPMODE, mga_mmio_base + PALWTADD); writeb( mga_grkey.ckey.op == CKEY_TRUE, mga_mmio_base + X_DATAREG); if ( mga_grkey.ckey.op == CKEY_TRUE ) { uint32_t r=0, g=0, b=0; writeb( XMULCTRL, mga_mmio_base + PALWTADD); switch (readb (mga_mmio_base + X_DATAREG)) { case BPP_8: /* Need to look up the color index, just using color 0 for now. */ break; case BPP_15: r = mga_grkey.ckey.red >> 3; g = mga_grkey.ckey.green >> 3; b = mga_grkey.ckey.blue >> 3; break; case BPP_16: r = mga_grkey.ckey.red >> 3; g = mga_grkey.ckey.green >> 2; b = mga_grkey.ckey.blue >> 3; break; case BPP_24: case BPP_32_DIR: case BPP_32_PAL: r = mga_grkey.ckey.red; g = mga_grkey.ckey.green; b = mga_grkey.ckey.blue; break; } // Disable color keying on alpha channel writeb( XCOLMSK, mga_mmio_base + PALWTADD); writeb( 0x00, mga_mmio_base + X_DATAREG); writeb( X_COLKEY, mga_mmio_base + PALWTADD); writeb( 0x00, mga_mmio_base + X_DATAREG); // Set up color key registers writeb( XCOLKEY0RED, mga_mmio_base + PALWTADD); writeb( r, mga_mmio_base + X_DATAREG); writeb( XCOLKEY0GREEN, mga_mmio_base + PALWTADD); writeb( g, mga_mmio_base + X_DATAREG); writeb( XCOLKEY0BLUE, mga_mmio_base + PALWTADD); writeb( b, mga_mmio_base + X_DATAREG); // Set up color key mask registers writeb( XCOLMSK0RED, mga_mmio_base + PALWTADD); writeb( 0xff, mga_mmio_base + X_DATAREG); writeb( XCOLMSK0GREEN, mga_mmio_base + PALWTADD); writeb( 0xff, mga_mmio_base + X_DATAREG); writeb( XCOLMSK0BLUE, mga_mmio_base + PALWTADD); writeb( 0xff, mga_mmio_base + X_DATAREG); } } // Backend Scaler writel( regs.besctl, mga_mmio_base + BESCTL); if(is_g400) writel( regs.beslumactl, mga_mmio_base + BESLUMACTL); writel( regs.bespitch, mga_mmio_base + BESPITCH); writel( regs.besa1org, mga_mmio_base + BESA1ORG); writel( regs.besa1corg, mga_mmio_base + BESA1CORG); writel( regs.besa2org, mga_mmio_base + BESA2ORG); writel( regs.besa2corg, mga_mmio_base + BESA2CORG); writel( regs.besb1org, mga_mmio_base + BESB1ORG); writel( regs.besb1corg, mga_mmio_base + BESB1CORG); writel( regs.besb2org, mga_mmio_base + BESB2ORG); writel( regs.besb2corg, mga_mmio_base + BESB2CORG); if(is_g400) { writel( regs.besa1c3org, mga_mmio_base + BESA1C3ORG); writel( regs.besa2c3org, mga_mmio_base + BESA2C3ORG); writel( regs.besb1c3org, mga_mmio_base + BESB1C3ORG); writel( regs.besb2c3org, mga_mmio_base + BESB2C3ORG); } writel( regs.beshcoord, mga_mmio_base + BESHCOORD); writel( regs.beshiscal, mga_mmio_base + BESHISCAL); writel( regs.beshsrcst, mga_mmio_base + BESHSRCST); writel( regs.beshsrcend, mga_mmio_base + BESHSRCEND); writel( regs.beshsrclst, mga_mmio_base + BESHSRCLST); writel( regs.besvcoord, mga_mmio_base + BESVCOORD); writel( regs.besviscal, mga_mmio_base + BESVISCAL); writel( regs.besv1srclst, mga_mmio_base + BESV1SRCLST); writel( regs.besv1wght, mga_mmio_base + BESV1WGHT); writel( regs.besv2srclst, mga_mmio_base + BESV2SRCLST); writel( regs.besv2wght, mga_mmio_base + BESV2WGHT); //update the registers somewhere between 1 and 2 frames from now. writel( regs.besglobctl + ((readl(mga_mmio_base + VCOUNT)+2)<<16), mga_mmio_base + BESGLOBCTL); #if 0 printf("[mga] wrote BES registers\n"); printf("[mga] BESCTL = 0x%08x\n", readl(mga_mmio_base + BESCTL)); printf("[mga] BESGLOBCTL = 0x%08x\n", readl(mga_mmio_base + BESGLOBCTL)); printf("[mga] BESSTATUS= 0x%08x\n", readl(mga_mmio_base + BESSTATUS)); #endif #ifdef CRTC2 // printf("c2ctl:0x%08x c2datactl:0x%08x\n",readl(mga_mmio_base + C2CTL),readl(mga_mmio_base + C2DATACTL)); // printf("c2misc:0x%08x\n",readl(mga_mmio_base + C2MISC)); // printf("c2ctl:0x%08x c2datactl:0x%08x\n",cregs.c2ctl,cregs.c2datactl); // writel(cregs.c2ctl, mga_mmio_base + C2CTL); writel(((readl(mga_mmio_base + C2CTL) & ~0x03e00000) + (cregs.c2ctl & 0x03e00000)), mga_mmio_base + C2CTL); writel(((readl(mga_mmio_base + C2DATACTL) & ~0x000000ff) + (cregs.c2datactl & 0x000000ff)), mga_mmio_base + C2DATACTL); // ctrc2 // disable CRTC2 acording to specs // writel(cregs.c2ctl & 0xfffffff0, mga_mmio_base + C2CTL); // je to treba ??? // writeb((readb(mga_mmio_base + XMISCCTRL) & 0x19) | 0xa2, mga_mmio_base + XMISCCTRL); // MAFC - mfcsel & vdoutsel // writeb((readb(mga_mmio_base + XMISCCTRL) & 0x19) | 0x92, mga_mmio_base + XMISCCTRL); // writeb((readb(mga_mmio_base + XMISCCTRL) & ~0xe9) + 0xa2, mga_mmio_base + XMISCCTRL); // writel(cregs.c2datactl, mga_mmio_base + C2DATACTL); // writel(cregs.c2hparam, mga_mmio_base + C2HPARAM); // writel(cregs.c2hsync, mga_mmio_base + C2HSYNC); // writel(cregs.c2vparam, mga_mmio_base + C2VPARAM); // writel(cregs.c2vsync, mga_mmio_base + C2VSYNC); writel(cregs.c2misc, mga_mmio_base + C2MISC); printf("c2offset = %d\n",cregs.c2offset); writel(cregs.c2offset, mga_mmio_base + C2OFFSET); writel(cregs.c2startadd0, mga_mmio_base + C2STARTADD0); // writel(cregs.c2startadd1, mga_mmio_base + C2STARTADD1); writel(cregs.c2pl2startadd0, mga_mmio_base + C2PL2STARTADD0); // writel(cregs.c2pl2startadd1, mga_mmio_base + C2PL2STARTADD1); writel(cregs.c2pl3startadd0, mga_mmio_base + C2PL3STARTADD0); // writel(cregs.c2pl3startadd1, mga_mmio_base + C2PL3STARTADD1); writel(cregs.c2spicstartadd0, mga_mmio_base + C2SPICSTARTADD0); // writel(cregs.c2spicstartadd1, mga_mmio_base + C2SPICSTARTADD1); // writel(cregs.c2subpiclut, mga_mmio_base + C2SUBPICLUT); // writel(cregs.c2preload, mga_mmio_base + C2PRELOAD); // finaly enable everything // writel(cregs.c2ctl, mga_mmio_base + C2CTL); // printf("c2ctl:0x%08x c2datactl:0x%08x\n",readl(mga_mmio_base + C2CTL),readl(mga_mmio_base + C2DATACTL)); // printf("c2misc:0x%08x\n", readl(mga_mmio_base + C2MISC)); #endif } #ifdef MGA_ALLOW_IRQ static void enable_irq(){ long int cc; cc = readl(mga_mmio_base + IEN); // printf("*** !!! IRQREG = %d\n", (int)(cc&0xff)); writeb( 0x11, mga_mmio_base + CRTCX); writeb(0x20, mga_mmio_base + CRTCD ); /* clear 0, enable off */ writeb(0x00, mga_mmio_base + CRTCD ); /* enable on */ writeb(0x10, mga_mmio_base + CRTCD ); /* clear = 1 */ writel( regs.besglobctl , mga_mmio_base + BESGLOBCTL); return; } static void disable_irq() { writeb( 0x11, mga_mmio_base + CRTCX); writeb(0x20, mga_mmio_base + CRTCD ); /* clear 0, enable off */ return; } void mga_handle_irq(int irq, void *dev_id/*, struct pt_regs *pregs*/) { // static int frame=0; // static int counter=0; long int cc; // if ( ! mga_enabled_flag ) return; // printf("vcount = %d\n",readl(mga_mmio_base + VCOUNT)); //printf("mga_interrupt #%d\n", irq); if ( irq != -1 ) { cc = readl(mga_mmio_base + STATUS); if ( ! (cc & 0x10) ) return; /* vsyncpen */ // debug_irqcnt++; } // if ( debug_irqignore ) { // debug_irqignore = 0; /* if ( mga_conf_deinterlace ) { if ( mga_first_field ) { // printf("mga_interrupt first field\n"); if ( syncfb_interrupt() ) mga_first_field = 0; } else { // printf("mga_interrupt second field\n"); mga_select_buffer( mga_current_field | 2 ); mga_first_field = 1; } } else { syncfb_interrupt(); } */ // frame=(frame+1)&1; regs.besctl = (regs.besctl & ~0x07000000) + (mga_next_frame << 25); writel( regs.besctl, mga_mmio_base + BESCTL ); #ifdef CRTC2 // sem pridat vyber obrazku !!!! crtc2_frame_sel(mga_next_frame); #endif #if 0 ++counter; if(!(counter&63)){ printf("mga irq counter = %d\n",counter); } #endif // } else { // debug_irqignore = 1; // } if ( irq != -1 ) { writeb( 0x11, mga_mmio_base + CRTCX); writeb( 0, mga_mmio_base + CRTCD ); writeb( 0x10, mga_mmio_base + CRTCD ); } // writel( regs.besglobctl, mga_mmio_base + BESGLOBCTL); return; } #endif /* MGA_ALLOW_IRQ */ int vixConfigPlayback(vidix_playback_t *config) { int x, y, sw, sh, dw, dh; int besleft, bestop, ifactor, ofsleft, ofstop, baseadrofs, weight, weights; int frame_size; #ifdef CRTC2 #define right_margin 0 #define left_margin 18 #define hsync_len 46 #define lower_margin 10 #define vsync_len 4 #define upper_margin 39 unsigned int hdispend = (config->src.w + 31) & ~31; unsigned int hsyncstart = hdispend + (right_margin & ~7); unsigned int hsyncend = hsyncstart + (hsync_len & ~7); unsigned int htotal = hsyncend + (left_margin & ~7); unsigned int vdispend = config->src.h; unsigned int vsyncstart = vdispend + lower_margin; unsigned int vsyncend = vsyncstart + vsync_len; unsigned int vtotal = vsyncend + upper_margin; #endif int frame; if ((config->num_frames < 1) || (config->num_frames > 4)) { printf("[mga] illegal num_frames: %d, setting to 2\n", config->num_frames); config->num_frames = 2; // return(EINVAL); } config->num_frames = 2; /* let it be for now */ x = config->dest.x; y = config->dest.y; sw = config->src.w; sh = config->src.h; dw = config->dest.w; dh = config->dest.h; config->dest.pitch.y=32; config->dest.pitch.u= config->dest.pitch.v=16; printf("[mga] Setting up a %dx%d+%d+%d video window (src %dx%d) format %X\n", dw, dh, x, y, sw, sh, config->fourcc); if ((sw < 4) || (sh < 4) || (dw < 4) || (dh < 4)) { printf("[mga] Invalid src/dest dimenstions\n"); return(EINVAL); } //FIXME check that window is valid and inside desktop // printf("[mga] vcount = %d\n", readl(mga_mmio_base + VCOUNT)); printf("[mga] mga_mmio_base = %p\n",mga_mmio_base); printf("[mga] mga_mem_base = %08x\n",mga_mem_base); switch(config->fourcc) { case IMGFMT_I420: case IMGFMT_IYUV: case IMGFMT_YV12: config->frame_size = ((sw + 31) & ~31) * sh + (((sw + 31) & ~31) * sh) / 2; break; case IMGFMT_YUY2: case IMGFMT_UYVY: config->frame_size = ((sw + 31) & ~31) * sh * 2; break; } // config->frame_size = config->src.h*config->src.w+(config->src.w*config->src.h)/2; frame_size = config->frame_size; config->offsets[0] = 0; config->offsets[1] = config->frame_size; /* ?? */ config->offset.y=0; config->offset.v=((sw + 31) & ~31) * sh; config->offset.u=config->offset.v+((sw + 31) & ~31) * sh /4; mga_src_base = (mga_ram_size*0x100000-config->num_frames*config->frame_size); if (mga_src_base < 0) { printf("[mga] not enough memory for frames!\n"); return(EFAULT); } mga_src_base &= (~0xFFFF); /* 64k boundary */ printf("[mga] YUV buffer base: %p\n", mga_src_base); config->dga_addr = mga_mem_base + mga_src_base; // config->offset.y = config->dga_addr; // config->offset.u = config->offset.y+config->frame_size; // config->offset.v = config->offset.u+2*config->frame_size; //FIXME figure out a better way to allocate memory on card //allocate 2 megs //mga_src_base = mga_mem_base + (MGA_VIDMEM_SIZE-2) * 0x100000; //mga_src_base = (MGA_VIDMEM_SIZE-3) * 0x100000; //Setup the BES registers for a three plane 4:2:0 video source regs.besglobctl = 0; switch(config->fourcc) { case IMGFMT_YV12: case IMGFMT_I420: case IMGFMT_IYUV: regs.besctl = 1 // BES enabled + (0<<6) // even start polarity + (1<<10) // x filtering enabled + (1<<11) // y filtering enabled + (1<<16) // chroma upsampling + (1<<17) // 4:2:0 mode + (1<<18); // dither enabled #if 0 if(is_g400) { //zoom disabled, zoom filter disabled, 420 3 plane format, proc amp //disabled, rgb mode disabled regs.besglobctl = (1<<5); } else { //zoom disabled, zoom filter disabled, Cb samples in 0246, Cr //in 1357, BES register update on besvcnt regs.besglobctl = 0; } #endif break; case IMGFMT_YUY2: regs.besctl = 1 // BES enabled + (0<<6) // even start polarity + (1<<10) // x filtering enabled + (1<<11) // y filtering enabled + (1<<16) // chroma upsampling + (0<<17) // 4:2:2 mode + (1<<18); // dither enabled regs.besglobctl = 0; // YUY2 format selected break; case IMGFMT_UYVY: regs.besctl = 1 // BES enabled + (0<<6) // even start polarity + (1<<10) // x filtering enabled + (1<<11) // y filtering enabled + (1<<16) // chroma upsampling + (0<<17) // 4:2:2 mode + (1<<18); // dither enabled regs.besglobctl = 1<<6; // UYVY format selected break; default: printf("[mga] Unsupported pixel format: %x\n", config->fourcc); return(ENOTSUP); } //Disable contrast and brightness control regs.besglobctl |= (1<<5) + (1<<7); regs.beslumactl = (0x7f << 16) + (0x80<<0); regs.beslumactl = 0x80<<0; //Setup destination window boundaries besleft = x > 0 ? x : 0; bestop = y > 0 ? y : 0; regs.beshcoord = (besleft<<16) + (x + dw-1); regs.besvcoord = (bestop<<16) + (y + dh-1); //Setup source dimensions regs.beshsrclst = (sw - 1) << 16; regs.bespitch = (sw + 31) & ~31 ; //Setup horizontal scaling ifactor = ((sw-1)<<14)/(dw-1); ofsleft = besleft - x; regs.beshiscal = ifactor<<2; regs.beshsrcst = (ofsleft*ifactor)<<2; regs.beshsrcend = regs.beshsrcst + (((dw - ofsleft - 1) * ifactor) << 2); //Setup vertical scaling ifactor = ((sh-1)<<14)/(dh-1); ofstop = bestop - y; regs.besviscal = ifactor<<2; baseadrofs = ((ofstop*regs.besviscal)>>16)*regs.bespitch; //frame_size = ((sw + 31) & ~31) * sh + (((sw + 31) & ~31) * sh) / 2; regs.besa1org = (uint32_t) mga_src_base + baseadrofs; regs.besa2org = (uint32_t) mga_src_base + baseadrofs + 1*frame_size; regs.besb1org = (uint32_t) mga_src_base + baseadrofs + 2*frame_size; regs.besb2org = (uint32_t) mga_src_base + baseadrofs + 3*frame_size; if(config->fourcc==IMGFMT_YV12 ||config->fourcc==IMGFMT_IYUV ||config->fourcc==IMGFMT_I420 ){ // planar YUV frames: if (is_g400) baseadrofs = (((ofstop*regs.besviscal)/4)>>16)*regs.bespitch; else baseadrofs = (((ofstop*regs.besviscal)/2)>>16)*regs.bespitch; if(config->fourcc==IMGFMT_YV12){ regs.besa1corg = (uint32_t) mga_src_base + baseadrofs + regs.bespitch * sh ; regs.besa2corg = (uint32_t) mga_src_base + baseadrofs + 1*frame_size + regs.bespitch * sh; regs.besb1corg = (uint32_t) mga_src_base + baseadrofs + 2*frame_size + regs.bespitch * sh; regs.besb2corg = (uint32_t) mga_src_base + baseadrofs + 3*frame_size + regs.bespitch * sh; regs.besa1c3org = regs.besa1corg + ((regs.bespitch * sh) / 4); regs.besa2c3org = regs.besa2corg + ((regs.bespitch * sh) / 4); regs.besb1c3org = regs.besb1corg + ((regs.bespitch * sh) / 4); regs.besb2c3org = regs.besb2corg + ((regs.bespitch * sh) / 4); } else { regs.besa1c3org = (uint32_t) mga_src_base + baseadrofs + regs.bespitch * sh ; regs.besa2c3org = (uint32_t) mga_src_base + baseadrofs + 1*frame_size + regs.bespitch * sh; regs.besb1c3org = (uint32_t) mga_src_base + baseadrofs + 2*frame_size + regs.bespitch * sh; regs.besb2c3org = (uint32_t) mga_src_base + baseadrofs + 3*frame_size + regs.bespitch * sh; regs.besa1corg = regs.besa1c3org + ((regs.bespitch * sh) / 4); regs.besa2corg = regs.besa2c3org + ((regs.bespitch * sh) / 4); regs.besb1corg = regs.besb1c3org + ((regs.bespitch * sh) / 4); regs.besb2corg = regs.besb2c3org + ((regs.bespitch * sh) / 4); } } weight = ofstop * (regs.besviscal >> 2); weights = weight < 0 ? 1 : 0; regs.besv2wght = regs.besv1wght = (weights << 16) + ((weight & 0x3FFF) << 2); regs.besv2srclst = regs.besv1srclst = sh - 1 - (((ofstop * regs.besviscal) >> 16) & 0x03FF); #ifdef CRTC2 // pridat hlavni registry - tj. casovani ... switch(config->fourcc){ case IMGFMT_YV12: case IMGFMT_I420: case IMGFMT_IYUV: cregs.c2ctl = 1 // CRTC2 enabled + (1<<1) // external clock + (0<<2) // external clock + (1<<3) // pixel clock enable - not needed ??? + (0<<4) // high prioryty req + (1<<5) // high prioryty req + (0<<6) // high prioryty req + (1<<8) // high prioryty req max + (0<<9) // high prioryty req max + (0<<10) // high prioryty req max + (0<<20) // CRTC1 to DAC + (1<<21) // 420 mode + (1<<22) // 420 mode + (1<<23) // 420 mode + (0<<24) // single chroma line for 420 mode - need to be corrected + (0<<25) /*/ interlace mode - need to be corrected*/ + (0<<26) // field legth polariry + (0<<27) // field identification polariry + (1<<28) // VIDRST detection mode + (0<<29) // VIDRST detection mode + (1<<30) // Horizontal counter preload + (1<<31) // Vertical counter preload ; cregs.c2datactl = 1 // disable dither - propably not needed, we are already in YUV mode + (1<<1) // Y filter enable + (1<<2) // CbCr filter enable + (0<<3) // subpicture enable (disabled) + (0<<4) // NTSC enable (disabled - PAL) + (0<<5) // C2 static subpicture enable (disabled) + (0<<6) // C2 subpicture offset division (disabled) + (0<<7) // 422 subformat selection ! /* + (0<<8) // 15 bpp high alpha + (0<<9) // 15 bpp high alpha + (0<<10) // 15 bpp high alpha + (0<<11) // 15 bpp high alpha + (0<<12) // 15 bpp high alpha + (0<<13) // 15 bpp high alpha + (0<<14) // 15 bpp high alpha + (0<<15) // 15 bpp high alpha + (0<<16) // 15 bpp low alpha + (0<<17) // 15 bpp low alpha + (0<<18) // 15 bpp low alpha + (0<<19) // 15 bpp low alpha + (0<<20) // 15 bpp low alpha + (0<<21) // 15 bpp low alpha + (0<<22) // 15 bpp low alpha + (0<<23) // 15 bpp low alpha + (0<<24) // static subpicture key + (0<<25) // static subpicture key + (0<<26) // static subpicture key + (0<<27) // static subpicture key + (0<<28) // static subpicture key */ ; break; case IMGFMT_YUY2: cregs.c2ctl = 1 // CRTC2 enabled + (1<<1) // external clock + (0<<2) // external clock + (1<<3) // pixel clock enable - not needed ??? + (0<<4) // high prioryty req - acc to spec + (1<<5) // high prioryty req + (0<<6) // high prioryty req // 7 reserved + (1<<8) // high prioryty req max + (0<<9) // high prioryty req max + (0<<10) // high prioryty req max // 11-19 reserved + (0<<20) // CRTC1 to DAC + (1<<21) // 422 mode + (0<<22) // 422 mode + (1<<23) // 422 mode + (0<<24) // single chroma line for 420 mode - need to be corrected + (0<<25) /*/ interlace mode - need to be corrected*/ + (0<<26) // field legth polariry + (0<<27) // field identification polariry + (1<<28) // VIDRST detection mode + (0<<29) // VIDRST detection mode + (1<<30) // Horizontal counter preload + (1<<31) // Vertical counter preload ; cregs.c2datactl = 1 // disable dither - propably not needed, we are already in YUV mode + (1<<1) // Y filter enable + (1<<2) // CbCr filter enable + (0<<3) // subpicture enable (disabled) + (0<<4) // NTSC enable (disabled - PAL) + (0<<5) // C2 static subpicture enable (disabled) + (0<<6) // C2 subpicture offset division (disabled) + (0<<7) // 422 subformat selection ! /* + (0<<8) // 15 bpp high alpha + (0<<9) // 15 bpp high alpha + (0<<10) // 15 bpp high alpha + (0<<11) // 15 bpp high alpha + (0<<12) // 15 bpp high alpha + (0<<13) // 15 bpp high alpha + (0<<14) // 15 bpp high alpha + (0<<15) // 15 bpp high alpha + (0<<16) // 15 bpp low alpha + (0<<17) // 15 bpp low alpha + (0<<18) // 15 bpp low alpha + (0<<19) // 15 bpp low alpha + (0<<20) // 15 bpp low alpha + (0<<21) // 15 bpp low alpha + (0<<22) // 15 bpp low alpha + (0<<23) // 15 bpp low alpha + (0<<24) // static subpicture key + (0<<25) // static subpicture key + (0<<26) // static subpicture key + (0<<27) // static subpicture key + (0<<28) // static subpicture key */ ; break; case IMGFMT_UYVY: cregs.c2ctl = 1 // CRTC2 enabled + (1<<1) // external clock + (0<<2) // external clock + (1<<3) // pixel clock enable - not needed ??? + (0<<4) // high prioryty req + (1<<5) // high prioryty req + (0<<6) // high prioryty req + (1<<8) // high prioryty req max + (0<<9) // high prioryty req max + (0<<10) // high prioryty req max + (0<<20) // CRTC1 to DAC + (1<<21) // 422 mode + (0<<22) // 422 mode + (1<<23) // 422 mode + (1<<24) // single chroma line for 420 mode - need to be corrected + (1<<25) /*/ interlace mode - need to be corrected*/ + (0<<26) // field legth polariry + (0<<27) // field identification polariry + (1<<28) // VIDRST detection mode + (0<<29) // VIDRST detection mode + (1<<30) // Horizontal counter preload + (1<<31) // Vertical counter preload ; cregs.c2datactl = 0 // enable dither - propably not needed, we are already in YUV mode + (1<<1) // Y filter enable + (1<<2) // CbCr filter enable + (0<<3) // subpicture enable (disabled) + (0<<4) // NTSC enable (disabled - PAL) + (0<<5) // C2 static subpicture enable (disabled) + (0<<6) // C2 subpicture offset division (disabled) + (1<<7) // 422 subformat selection ! /* + (0<<8) // 15 bpp high alpha + (0<<9) // 15 bpp high alpha + (0<<10) // 15 bpp high alpha + (0<<11) // 15 bpp high alpha + (0<<12) // 15 bpp high alpha + (0<<13) // 15 bpp high alpha + (0<<14) // 15 bpp high alpha + (0<<15) // 15 bpp high alpha + (0<<16) // 15 bpp low alpha + (0<<17) // 15 bpp low alpha + (0<<18) // 15 bpp low alpha + (0<<19) // 15 bpp low alpha + (0<<20) // 15 bpp low alpha + (0<<21) // 15 bpp low alpha + (0<<22) // 15 bpp low alpha + (0<<23) // 15 bpp low alpha + (0<<24) // static subpicture key + (0<<25) // static subpicture key + (0<<26) // static subpicture key + (0<<27) // static subpicture key + (0<<28) // static subpicture key */ ; break; default: printf("[mga] Unsupported pixel format: %x\n",config->fourcc); return(ENOTSUP); } cregs.c2hparam=((hdispend - 8) << 16) | (htotal - 8); cregs.c2hsync=((hsyncend - 8) << 16) | (hsyncstart - 8); cregs.c2misc=0 // CRTCV2 656 togg f0 +(0<<1) // CRTCV2 656 togg f0 +(0<<2) // CRTCV2 656 togg f0 +(0<<4) // CRTCV2 656 togg f1 +(0<<5) // CRTCV2 656 togg f1 +(0<<6) // CRTCV2 656 togg f1 +(0<<8) // Hsync active high +(0<<9) // Vsync active high // 16-27 c2vlinecomp - nevim co tam dat ; cregs.c2offset=(regs.bespitch << 1); cregs.c2pl2startadd0=regs.besa1corg; // cregs.c2pl2startadd1=regs.besa2corg; cregs.c2pl3startadd0=regs.besa1c3org; // cregs.c2pl3startadd1=regs.besa2c3org; cregs.c2preload=(vsyncstart << 16) | (hsyncstart); // from cregs.c2spicstartadd0=0; // not used // cregs.c2spicstartadd1=0; // not used cregs.c2startadd0=regs.besa1org; // cregs.c2startadd1=regs.besa2org; cregs.c2subpiclut=0; //not used cregs.c2vparam=((vdispend - 1) << 16) | (vtotal - 1); cregs.c2vsync=((vsyncend - 1) << 16) | (vsyncstart - 1); #endif mga_vid_write_regs(0); return(0); } int vixPlaybackOn(void) { printf("[mga] playback on\n"); vid_src_ready = 1; if(vid_overlay_on) { regs.besctl |= 1; mga_vid_write_regs(0); } #ifdef MGA_ALLOW_IRQ if (mga_irq != -1) enable_irq(); #endif mga_next_frame=0; return(0); } int vixPlaybackOff(void) { printf("[mga] playback off\n"); vid_src_ready = 0; #ifdef MGA_ALLOW_IRQ if (mga_irq != -1) disable_irq(); #endif regs.besctl &= ~1; regs.besglobctl &= ~(1<<6); /* UYVY format selected */ mga_vid_write_regs(0); return(0); } static int mga_vid_release(/*struct inode *inode, struct file *file*/) { //Close the window just in case printf("[mga] Video OFF (release)\n"); vid_src_ready = 0; regs.besctl &= ~1; regs.besglobctl &= ~(1<<6); // UYVY format selected // mga_config.colkey_on=0; //!!! mga_vid_write_regs(1); mga_vid_in_use = 0; // MOD_DEC_USE_COUNT; return 0; } int vixProbe(int verbose,int force) { pciinfo_t lst[MAX_PCI_DEVICES]; unsigned int i, num_pci; int err; printf("[mga] probe\n"); mga_verbose = verbose; is_g400 = -1; err = pci_scan(&lst, &num_pci); if (err) { printf("[mga] Error occured during pci scan: %s\n", strerror(err)); return(err); } if (mga_verbose > 1) printf("[mga] found %d pci devices\n", num_pci); for (i = 0; i < num_pci; i++) { if (mga_verbose > 2) printf("pci[%d] vendor: %d device: %d\n", i, lst[i].vendor, lst[i].device); if (lst[i].vendor == VENDOR_MATROX) { switch(lst[i].device) { case DEVICE_MATROX_MGA_G550_AGP: printf("[mga] Found MGA G550\n"); is_g400 = 1; goto card_found; case DEVICE_MATROX_MGA_G400_AGP: printf("[mga] Found MGA G400/G450\n"); is_g400 = 1; goto card_found; case DEVICE_MATROX_MGA_G200_AGP: printf("[mga] Found MGA G200 AGP\n"); is_g400 = 0; goto card_found; case DEVICE_MATROX_MGA_G200: printf("[mga] Found MGA G200 PCI\n"); is_g400 = 0; goto card_found; } } } if (is_g400 == -1) { printf("[mga] No supported cards found\n"); return(ENXIO); } card_found: probed = 1; memcpy(&pci_info, &lst[i], sizeof(pciinfo_t)); mga_cap.device_id = pci_info.device; /* set device id in capabilites */ return(0); } int vixInit(void) { unsigned int card_option; printf("[mga] init\n"); mga_vid_in_use = 0; printf("Matrox MGA G200/G400/G450 YUV Video interface v2.01 (c) Aaron Holtzman & A'rpi\n"); if (!probed) { printf("[mga] driver was not probed but is being initializing\n"); return(EINTR); } #if 0 #if LINUX_VERSION_CODE >= 0x020300 mga_mmio_base = ioremap_nocache(dev->resource[1].start,0x4000); mga_mem_base = dev->resource[0].start; #else mga_mmio_base = ioremap_nocache(dev->base_address[1] & PCI_BASE_ADDRESS_MEM_MASK,0x4000); mga_mem_base = dev->base_address[0] & PCI_BASE_ADDRESS_MEM_MASK; #endif #endif #warning "FIXME: implement pciconfig_read! (or enable syscall)\n" #if 0 /* from linux/pci.h */ #define PCI_DEVFN(slot, func) ((((slot) & 0x1f) << 3) | ((func) & 0x07)) pci_config_read(pci_info.bus, PCI_DEVFN(pci_info.card, pci_info.func), 0x40, 4, &card_option); // pci_read_config_dword(dev, 0x40, &card_option); printf("[mga] OPTION word: 0x%08X mem: 0x%02X %s\n", card_option, (card_option>>10)&0x17, ((card_option>>14)&1)?"SGRAM":"SDRAM"); #endif // temp = (card_option >> 10) & 0x17; if (mga_ram_size) { printf("[mga] RAMSIZE forced to %d MB\n", mga_ram_size); } else { #ifdef MGA_MEMORY_SIZE mga_ram_size = MGA_MEMORY_SIZE; printf("[mga] hard-coded RAMSIZE is %d MB\n", (unsigned int) mga_ram_size); #else if (is_g400) { switch((card_option>>10)&0x17) { // SDRAM: case 0x00: case 0x04: mga_ram_size = 16; break; case 0x03: mga_ram_size = 32; break; // SGRAM: case 0x10: case 0x14: mga_ram_size = 32; break; case 0x11: case 0x12: mga_ram_size = 16; break; default: mga_ram_size = 16; printf("[mga] Couldn't detect RAMSIZE, assuming 16MB!\n"); } } else { switch((card_option>>10)&0x17) { // case 0x10: // case 0x13: mga_ram_size = 8; break; default: mga_ram_size = 8; } } #if 0 // printf("List resources -----------\n"); for(temp=0;temp<DEVICE_COUNT_RESOURCE;temp++){ struct resource *res=&pci_dev->resource[temp]; if(res->flags){ int size=(1+res->end-res->start)>>20; printf("res %d: start: 0x%X end: 0x%X (%d MB) flags=0x%X\n",temp,res->start,res->end,size,res->flags); if(res->flags&(IORESOURCE_MEM|IORESOURCE_PREFETCH)){ if(size>mga_ram_size && size<=64) mga_ram_size=size; } } } #endif printf("[mga] detected RAMSIZE is %d MB\n", (unsigned int) mga_ram_size); #endif } if (mga_ram_size) { if ((mga_ram_size < 4) || (mga_ram_size > 64)) { printf("[mga] invalid RAMSIZE: %d MB\n", mga_ram_size); return(EINVAL); } } printf("[mga] hardware addresses: mmio: %p, framebuffer: %p\n", pci_info.base1, pci_info.base0); mga_mmio_base = map_phys_mem(pci_info.base1,0x4000); mga_mem_base = map_phys_mem(pci_info.base0,mga_ram_size*1024*1024); printf("[mga] MMIO at %p, IRQ: %d, framebuffer: %p\n", mga_mmio_base, mga_irq, mga_mem_base); #ifdef MGA_ALLOW_IRQ if (mga_irq != -1) { int tmp = request_irq(mga_irq, mga_handle_irq, SA_INTERRUPT | SA_SHIRQ, "Syncfb Time Base", &mga_irq); if (tmp) { printf("syncfb (mga): cannot register irq %d (Err: %d)\n", mga_irq, tmp); mga_irq=-1; } else { printf("syncfb (mga): registered irq %d\n", mga_irq); } } else { printf("syncfb (mga): No valid irq was found\n"); mga_irq=-1; } #else printf("syncfb (mga): IRQ disabled in mga_vid.c\n"); mga_irq=-1; #endif return(0); } void vixDestroy(void) { printf("[mga] destroy\n"); #ifdef MGA_ALLOW_IRQ if (mga_irq != -1) free_irq(mga_irq, &mga_irq); #endif if (mga_mmio_base) unmap_phys_mem(mga_mmio_base, 0x4000); if (mga_mem_base) unmap_phys_mem(mga_mem_base, mga_ram_size); /* FIXME turn off BES */ return; } int vixQueryFourcc(vidix_fourcc_t *to) { printf("[mga] query fourcc (%x)\n", to->fourcc); switch(to->fourcc) { case IMGFMT_YV12: case IMGFMT_IYUV: case IMGFMT_I420: case IMGFMT_YUY2: case IMGFMT_UYVY: break; default: to->depth = to->flags = 0; return(ENOTSUP); } to->depth = VID_DEPTH_12BPP | VID_DEPTH_15BPP | VID_DEPTH_16BPP | VID_DEPTH_24BPP | VID_DEPTH_32BPP; to->flags = VID_CAP_EXPAND | VID_CAP_SHRINK | VID_CAP_COLORKEY; return(0); } unsigned int vixGetVersion(void) { return(VIDIX_VERSION); } int vixGetCapability(vidix_capability_t *to) { memcpy(to, &mga_cap, sizeof(vidix_capability_t)); return(0); } int vixGetGrKeys(vidix_grkey_t *grkey) { memcpy(grkey, &mga_grkey, sizeof(vidix_grkey_t)); return(0); } int vixSetGrKeys(const vidix_grkey_t *grkey) { memcpy(&mga_grkey, grkey, sizeof(vidix_grkey_t)); return(0); } #ifdef TEST_ME_PLEASE vidix_video_eq_t equal = { 0, 0, 0, 0, 0, 0, 0, 0 }; int vixPlaybackSetEq( const vidix_video_eq_t * eq) { uint32_t beslumactl; int brightness,contrast; memcpy(&equal,eq,sizeof(vidix_video_eq_t)); //Enable contrast and brightness control writel(readl(mga_mmio_base + BESGLOBCTL) & ~((1<<5) + (1<<7)),mga_mmio_base + BESGLOBCTL); brightness = (equal.brightness * 128) / 1000; if(brightness < -128) brightness = -128; if(brightness > 127) brightness = 127; contrast = ((equal.contrast + 1000) * 128) / 1000; if(contrast < 0) contrast = 0; if(contrast > 255) contrast = 255; beslumactl = ((brightness & 0xff) << 16) | (contrast & 0xff); writel(beslumactl,mga_mmio_base + BESLUMACTL); return 0; } int vixPlaybackGetEq( vidix_video_eq_t * eq) { memcpy(eq,&equal,sizeof(vidix_video_eq_t)); return 0; } #endif