/* * Copyright (c) 2006 Advanced Micro Devices, Inc. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER * DEALINGS IN THE SOFTWARE. * * Neither the name of the Advanced Micro Devices, Inc. nor the names of its * contributors may be used to endorse or promote products derived from this * software without specific prior written permission. */ /* * Cimarron VOP configuration routines. */ /*--------------------------------------------------------------------------- * vop_set_vbi_window * * This routine configures the output position and location in memory of * VBI data. *--------------------------------------------------------------------------*/ int vop_set_vbi_window(VOPVBIWINDOWBUFFER * buffer) { unsigned long unlock, temp; unsigned long hstart, hstop; unsigned long htotal, hsyncstart; if (!buffer) return CIM_STATUS_INVALIDPARAMS; unlock = READ_REG32(DC3_UNLOCK); WRITE_REG32(DC3_UNLOCK, DC3_UNLOCK_VALUE); /* PROGRAM HORIZONTAL POSITION * The horizontal position is a little tricky. The counter for the * horizontal timings is reused for the VBI counter. Consequently, the * horizontal start and stop values are based off the beginning of active * data. However, the VG has a quirk. If the counter start position is * before the beginning of HSync, it applies to the previous line. If * the counter is after the beginning of HSync it applies to the current * line. So, for one line the real range can be thought of as * HSync_start to (HSync_start + htotal - 1). However, the counters * must be between 0 and htotal - 1. When placing VBI data before the * start of active data, the horizontal end position will thus be *less* * than the horizontal start. */ htotal = ((READ_REG32(DC3_H_ACTIVE_TIMING) >> 16) & 0xFFF) + 1; hsyncstart = (READ_REG32(DC3_H_SYNC_TIMING) & 0xFFF) + 1; if (buffer->horz_from_hsync) { /* VERIFY THAT THE INPUT IS VALID */ if (buffer->horz_start < 0 || (buffer->horz_start + buffer->vbi_width) > htotal) return CIM_STATUS_INVALIDPARAMS; hstart = buffer->horz_start + hsyncstart; } else { /* VERIFY THAT THE INPUT IS VALID */ if (buffer->horz_start < ((long) hsyncstart - (long) htotal) || buffer->horz_start > (long) hsyncstart || buffer->vbi_width > htotal) { return CIM_STATUS_INVALIDPARAMS; } hstart = buffer->horz_start + htotal; } hstop = hstart + buffer->vbi_width; if (hstart > htotal) hstart -= htotal; if (hstop > htotal) hstop -= htotal; hstart--; hstop--; WRITE_REG32(DC3_VBI_HOR, ((hstop << DC3_VBI_HOR_END_SHIFT) & DC3_VBI_HOR_END_MASK) | (hstart & DC3_VBI_HOR_START_MASK)); /* WRITE LINE CAPTURE MASKS */ WRITE_REG32(DC3_VBI_LN_ODD, ((buffer->odd_line_offset << DC3_VBI_ODD_LINE_SHIFT) & DC3_VBI_ODD_LINE_MASK) | (buffer-> odd_line_capture_mask & DC3_VBI_ODD_ENABLE_MASK)); WRITE_REG32(DC3_VBI_LN_EVEN, ((buffer->even_line_offset << DC3_VBI_EVEN_LINE_SHIFT) & DC3_VBI_EVEN_LINE_MASK) | (buffer-> even_line_capture_mask & DC3_VBI_EVEN_ENABLE_MASK)); /* PROGRAM SOURCE OFFSETS * Start with the even offsets. Note that we always enable 16-bit VBI, * as this is the only way to get VBI data on each VOP clock. */ temp = READ_REG32(DC3_VBI_EVEN_CTL) & ~DC3_VBI_EVEN_CTL_OFFSET_MASK; temp |= DC3_VBI_EVEN_CTL_ENABLE_16; if (buffer->enable_upscale) temp |= DC3_VBI_EVEN_CTL_UPSCALE; WRITE_REG32(DC3_VBI_EVEN_CTL, temp | (buffer->even_address_offset & DC3_VBI_EVEN_CTL_OFFSET_MASK)); /* ODD OFFSET */ temp = READ_REG32(DC3_VBI_ODD_CTL) & ~DC3_VBI_ODD_CTL_OFFSET_MASK; WRITE_REG32(DC3_VBI_ODD_CTL, temp | (buffer->odd_address_offset & DC3_VBI_ODD_CTL_OFFSET_MASK)); /* PITCH */ temp = ((buffer->data_size >> 3) << 16) | ((buffer->data_pitch >> 3) & 0x0000FFFF); WRITE_REG32(DC3_VBI_PITCH, temp); WRITE_REG32(DC3_UNLOCK, unlock); return CIM_STATUS_OK; } /*--------------------------------------------------------------------------- * vop_enable_vbi_output * * This routine enables/disables VBI fetching inside the video generator. *--------------------------------------------------------------------------*/ int vop_enable_vbi_output(int enable) { unsigned long unlock, temp; unlock = READ_REG32(DC3_UNLOCK); temp = READ_REG32(DC3_VBI_EVEN_CTL); if (enable) temp |= DC3_VBI_ENABLE; else temp &= ~DC3_VBI_ENABLE; WRITE_REG32(DC3_UNLOCK, DC3_UNLOCK_VALUE); WRITE_REG32(DC3_VBI_EVEN_CTL, temp); WRITE_REG32(DC3_UNLOCK, unlock); return CIM_STATUS_OK; } /*--------------------------------------------------------------------------- * vop_set_configuration * * This routine is passed a VOP_CONFIGURATION structure that contains all * the necessary information to configure VOP output. *--------------------------------------------------------------------------*/ int vop_set_configuration(VOPCONFIGURATIONBUFFER * config) { unsigned long vop_config = 0; unsigned long alpha, control2; unsigned long unlock; unsigned long delta; Q_WORD msr_value; int rgb = 0; if (!config) return CIM_STATUS_INVALIDPARAMS; unlock = READ_REG32(DC3_UNLOCK); delta = READ_REG32(DC3_VID_DS_DELTA) & DC3_DS_DELTA_MASK; /* OVERRIDE THE OUTPUT SETTINGS TO ENABLE VOP OUTPUT */ if (config->mode != VOP_MODE_DISABLED) { msr_read64(MSR_DEVICE_GEODELX_DF, MSR_GEODELINK_CONFIG, &msr_value); msr_value.low &= ~DF_CONFIG_OUTPUT_MASK; msr_value.low |= DF_OUTPUT_VOP; msr_write64(MSR_DEVICE_GEODELX_DF, MSR_GEODELINK_CONFIG, &msr_value); } /* SET THE UNIVERSAL VOP OPTIONS */ if (config->flags & VOP_FLAG_SWAP_UV) vop_config |= VOP_CONFIG_SWAPUV; if (config->flags & VOP_FLAG_SWAP_VBI) vop_config |= VOP_CONFIG_SWAPVBI; /* SET THE MODE SPECIFIC PARAMETERS */ if (config->mode == VOP_MODE_601) { vop_config |= config->vop601.flags; vop_config |= config->vop601.vsync_shift; vop_config |= VOP_CONFIG_ENABLE_601 | VOP_CONFIG_VIP2_0; switch (config->vop601.output_mode) { case VOP_601_YUV_16BIT: vop_config |= VOP_CONFIG_VIP2_16BIT; break; case VOP_601_YUV_4_4_4: vop_config |= VOP_CONFIG_DISABLE_DECIMATE; break; case VOP_601_RGB_8_8_8: vop_config |= VOP_CONFIG_DISABLE_DECIMATE | VOP_CONFIG_RGBMODE; rgb = 1; break; } if (config->vop601.vsync_shift == VOP_VSYNC_LATER_BY_X) { delta |= (config->vop601.vsync_shift_count & DC3_601_VSYNC_SHIFT_MASK); delta |= DC3_601_VSYNC_SHIFT_ENABLE; } } else { if (config->flags & VOP_FLAG_VBI) vop_config |= VOP_CONFIG_VBI; if (config->flags & VOP_FLAG_TASK) vop_config |= VOP_CONFIG_TASK; if (config->flags & VOP_FLAG_SINGLECHIPCOMPAT) vop_config |= VOP_CONFIG_SC_COMPATIBLE; if (config->flags & VOP_FLAG_EXTENDEDSAV) vop_config |= VOP_CONFIG_EXTENDED_SAV; switch (config->mode) { case VOP_MODE_DISABLED: vop_config |= VOP_CONFIG_DISABLED; break; case VOP_MODE_VIP11: vop_config |= VOP_CONFIG_VIP1_1; break; case VOP_MODE_CCIR656: vop_config |= VOP_CONFIG_CCIR656; break; case VOP_MODE_VIP20_8BIT: vop_config |= VOP_CONFIG_VIP2_0; break; case VOP_MODE_VIP20_16BIT: vop_config |= VOP_CONFIG_VIP2_0 | VOP_CONFIG_VIP2_16BIT; break; } } /* SET THE 4:4:4 TO 4:2:2 DECIMATION ALGORITHM */ vop_config |= (config->conversion_mode); /* SET THE VSYNC OUT OPTIONS */ control2 = READ_VIP32(VIP_CONTROL2) & ~VIP_CONTROL2_SYNC2PIN_MASK; control2 |= config->vsync_out; WRITE_VIP32(VIP_CONTROL2, control2); /* FORCE THE CORRECT VOP COLOR SPACE */ /* The output of the mixer will be either RGB or YUV. We must enable */ /* or disable the VOP CSC based on the desired output format. */ alpha = READ_VID32(DF_VID_ALPHA_CONTROL); if (!(alpha & DF_CSC_GRAPHICS_RGB_TO_YUV)) { /* RGB OUTPUT FROM THE MIXER */ if (!rgb) alpha |= DF_CSC_VOP_RGB_TO_YUV; else alpha &= ~DF_CSC_VOP_RGB_TO_YUV; } else { /* YUV OUTPUT FROM THE MIXER */ /* As there is no YUV->RGB VOP conversion, we simply disable the */ /* VOP CSC and trust that the user is competent. */ alpha &= ~DF_CSC_VOP_RGB_TO_YUV; } /* AND WRITE THE CONFIGURATION */ WRITE_VID32(DF_VID_ALPHA_CONTROL, alpha); WRITE_VOP32(VOP_CONFIGURATION, vop_config); WRITE_REG32(DC3_UNLOCK, DC3_UNLOCK_VALUE); WRITE_REG32(DC3_VID_DS_DELTA, delta); WRITE_REG32(DC3_UNLOCK, unlock); return CIM_STATUS_OK; } /*--------------------------------------------------------------------------- * vop_save_state * * This routine saves the necessary register contents in order to restore * at a later point to the same state. Note that the capture state is * forced to OFF in this routine. *--------------------------------------------------------------------------*/ int vop_save_state(VOPSTATEBUFFER * save_buffer) { if (!save_buffer) return CIM_STATUS_INVALIDPARAMS; save_buffer->config = READ_VOP32(VOP_CONFIGURATION); return CIM_STATUS_OK; } /*--------------------------------------------------------------------------- * vop_restore_state * * This routine restores the state of the vop registers - which were * previously saved using vop_save_state. *--------------------------------------------------------------------------*/ int vop_restore_state(VOPSTATEBUFFER * restore_buffer) { if (!restore_buffer) return CIM_STATUS_INVALIDPARAMS; WRITE_VOP32(VOP_CONFIGURATION, restore_buffer->config); return CIM_STATUS_OK; } /*+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ * CIMARRON VOP READ ROUTINES * These routines are included for use in diagnostics or when debugging. They * can be optionally excluded from a project. *++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++*/ #if CIMARRON_INCLUDE_VOP_READ_ROUTINES /*--------------------------------------------------------------------------- * vop_get_current_mode * * This routine reads the current VIP operating mode and stores it in the * passed VOP_CONFIGURATION structure. *--------------------------------------------------------------------------*/ int vop_get_current_mode(VOPCONFIGURATIONBUFFER * config) { unsigned long vop_config = 0; unsigned long alpha; if (!config) return CIM_STATUS_INVALIDPARAMS; vop_config = READ_VOP32(VOP_CONFIGURATION); alpha = READ_VID32(DF_VID_ALPHA_CONTROL); /* READ THE CURRENT MODE */ switch (vop_config & VOP_CONFIG_MODE_MASK) { case VOP_CONFIG_DISABLED: config->mode = VOP_MODE_DISABLED; break; case VOP_CONFIG_VIP1_1: config->mode = VOP_MODE_VIP11; break; case VOP_CONFIG_CCIR656: config->mode = VOP_MODE_CCIR656; break; case VOP_CONFIG_VIP2_0: if (vop_config & VOP_CONFIG_ENABLE_601) config->mode = VOP_MODE_601; else if (vop_config & VOP_CONFIG_VIP2_16BIT) config->mode = VOP_MODE_VIP20_16BIT; else config->mode = VOP_MODE_VIP20_8BIT; break; } /* READ 601 SETTINGS */ config->vop601.flags = vop_config & (VOP_CONFIG_INVERT_DISPE | VOP_CONFIG_INVERT_HSYNC | VOP_CONFIG_INVERT_VSYNC); config->vop601.vsync_shift = vop_config & VOP_CONFIG_VSYNC_MASK; config->vop601.vsync_shift_count = READ_REG32(DC3_VID_DS_DELTA) & DC3_601_VSYNC_SHIFT_MASK; if ((alpha & DF_CSC_GRAPHICS_RGB_TO_YUV) || (alpha & DF_CSC_VOP_RGB_TO_YUV)) { /* YUV OUTPUT */ if (vop_config & VOP_CONFIG_DISABLE_DECIMATE) config->vop601.output_mode = VOP_601_YUV_4_4_4; else if (vop_config & VOP_CONFIG_VIP2_16BIT) config->vop601.output_mode = VOP_601_YUV_16BIT; else config->vop601.output_mode = VOP_601_YUV_8BIT; } else { config->vop601.output_mode = VOP_601_RGB_8_8_8; } config->flags = 0; /* READ THE UNIVERSAL VOP OPTIONS */ if (vop_config & VOP_CONFIG_SWAPUV) config->flags |= VOP_FLAG_SWAP_UV; if (vop_config & VOP_CONFIG_SWAPVBI) config->flags |= VOP_FLAG_SWAP_VBI; if (vop_config & VOP_CONFIG_VBI) config->flags |= VOP_FLAG_VBI; if (vop_config & VOP_CONFIG_TASK) config->flags |= VOP_FLAG_TASK; if (vop_config & VOP_CONFIG_SC_COMPATIBLE) config->flags |= VOP_FLAG_SINGLECHIPCOMPAT; if (vop_config & VOP_CONFIG_EXTENDED_SAV) config->flags |= VOP_FLAG_EXTENDEDSAV; config->conversion_mode = vop_config & VOP_CONFIG_422_MASK; config->vsync_out = READ_VIP32(VIP_CONTROL2) & VIP_CONTROL2_SYNC2PIN_MASK; return CIM_STATUS_OK; } /*--------------------------------------------------------------------------- * vop_get_vbi_window * * This routine reads the current VBI configuration for VOP output. *--------------------------------------------------------------------------*/ int vop_get_vbi_configuration(VOPVBIWINDOWBUFFER * buffer) { unsigned long temp; unsigned long hstart, hstop; unsigned long htotal, hsyncstart; if (!buffer) return CIM_STATUS_INVALIDPARAMS; htotal = ((READ_REG32(DC3_H_ACTIVE_TIMING) >> 16) & 0xFFF) + 1; hsyncstart = (READ_REG32(DC3_H_SYNC_TIMING) & 0xFFF) + 1; /* DECODE HORIZONTAL POSITION */ /* This is done according to the requested horizontal origin */ temp = READ_REG32(DC3_VBI_HOR); hstart = (temp & DC3_VBI_HOR_START_MASK) + 1; hstop = ((temp & DC3_VBI_HOR_END_MASK) >> DC3_VBI_HOR_END_SHIFT) + 1; if (buffer->horz_from_hsync) { buffer->horz_start = hstart + htotal - hsyncstart; if (buffer->horz_start >= (long) htotal) buffer->horz_start -= htotal; } else { if (hstart > hsyncstart) buffer->horz_start = (long) hstart - (long) htotal; else buffer->horz_start = hstart; } if (hstop > hstart) buffer->vbi_width = hstop - hstart; else buffer->vbi_width = (htotal - hstart) + hstop; /* READ LINE MASKS */ temp = READ_REG32(DC3_VBI_LN_ODD); buffer->odd_line_offset = (temp & DC3_VBI_ODD_LINE_MASK) >> DC3_VBI_ODD_LINE_SHIFT; buffer->odd_line_capture_mask = (temp & DC3_VBI_ODD_ENABLE_MASK); temp = READ_REG32(DC3_VBI_LN_EVEN); buffer->even_line_offset = (temp & DC3_VBI_EVEN_LINE_MASK) >> DC3_VBI_EVEN_LINE_SHIFT; buffer->even_line_capture_mask = (temp & DC3_VBI_EVEN_ENABLE_MASK); /* READ VBI UPSCALE SETTINGS */ buffer->enable_upscale = 0; temp = READ_REG32(DC3_VBI_EVEN_CTL); if (temp & DC3_VBI_EVEN_CTL_UPSCALE) buffer->enable_upscale = 1; /* READ SOURCE OFFSETS */ buffer->even_address_offset = temp & DC3_VBI_EVEN_CTL_OFFSET_MASK; buffer->odd_address_offset = READ_REG32(DC3_VBI_ODD_CTL) & DC3_VBI_ODD_CTL_OFFSET_MASK; /* PITCH AND SIZE */ temp = READ_REG32(DC3_VBI_PITCH); buffer->data_size = (temp >> 16) << 3; buffer->data_pitch = (temp & 0xFFFF); return CIM_STATUS_OK; } /*--------------------------------------------------------------------------- * vop_get_vbi_enable * * This routine reads the current enable status of VBI output. *--------------------------------------------------------------------------*/ int vop_get_vbi_enable(void) { if (READ_REG32(DC3_VBI_EVEN_CTL) & DC3_VBI_ENABLE) return 1; return 0; } /*--------------------------------------------------------------------------- * vop_get_crc * * This routine returns a CRC of the current VOP data --------------------------------------------------------------------------*/ unsigned long vop_get_crc(void) { unsigned long crc; unsigned long config = READ_VOP32(VOP_CONFIGURATION); unsigned long timeout = 1000; if (!(READ_REG32(DC3_DISPLAY_CFG) & DC3_DCFG_TGEN)) return 0xFFFFFFFF; /* RESET CRC */ WRITE_VOP32(VOP_CONFIGURATION, config & ~VOP_CONFIG_ENABLE_SIGNATURE); /* WAIT FOR THE RESET TO BE LATCHED */ while ((READ_VOP32(VOP_SIGNATURE) != 0x00000001) && timeout) timeout--; WRITE_VOP32(VOP_CONFIGURATION, config | VOP_CONFIG_ENABLE_SIGNATURE); /* WAIT UNTIL NOT ACTIVE, THEN ACTIVE, NOT ACTIVE, THEN ACTIVE */ while (!(READ_VOP32(VOP_CONFIGURATION) & VOP_CONFIG_SIGVAL)); crc = READ_VOP32(VOP_SIGNATURE); return crc; } /*--------------------------------------------------------------------------- * vop_read_vbi_crc * * This routine returns a CRC of the current VBI data ---------------------------------------------------------------------------*/ unsigned long vop_read_vbi_crc(void) { unsigned long gcfg, unlock, vbi_even; unsigned long crc; if (!(READ_REG32(DC3_DISPLAY_CFG) & DC3_DCFG_TGEN) || !(READ_REG32(DC3_VBI_EVEN_CTL) & DC3_VBI_ENABLE)) { return 0xFFFFFFFF; } unlock = READ_REG32(DC3_UNLOCK); gcfg = READ_REG32(DC3_GENERAL_CFG); vbi_even = READ_REG32(DC3_VBI_EVEN_CTL); gcfg |= DC3_GCFG_SGRE | DC3_GCFG_CRC_MODE; gcfg &= ~(DC3_GCFG_SGFR | DC3_GCFG_SIG_SEL); vbi_even |= DC3_VBI_EVEN_ENABLE_CRC; WRITE_REG32(DC3_UNLOCK, DC3_UNLOCK_VALUE); WRITE_REG32(DC3_VBI_EVEN_CTL, vbi_even); WRITE_REG32(DC3_GENERAL_CFG, gcfg & ~DC3_GCFG_SIGE); WRITE_REG32(DC3_GENERAL_CFG, gcfg | DC3_GCFG_SIGE); /* WAIT FOR THE CRC TO BE COMPLETED */ while (!(READ_REG32(DC3_LINE_CNT_STATUS) & DC3_LNCNT_SIGC)); /* READ THE COMPLETED CRC */ crc = READ_REG32(DC3_PAL_DATA); /* RESTORE THE PALETTE SETTINGS */ gcfg &= ~DC3_GCFG_SGRE; WRITE_REG32(DC3_GENERAL_CFG, gcfg); WRITE_REG32(DC3_UNLOCK, unlock); return crc; } #endif