kolibrios/drivers/video/drm/radeon/rdisplay.c

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#include <drm/drmP.h>
#include <drm/radeon_drm.h>
#include "radeon.h"
#include "radeon_object.h"
#include "bitmap.h"
#include "display.h"
#include "r100d.h"
display_t *os_display;
static cursor_t* __stdcall select_cursor(cursor_t *cursor);
static void __stdcall move_cursor(cursor_t *cursor, int x, int y);
extern void __attribute__((regparm(1))) destroy_cursor(cursor_t *cursor);
void disable_mouse(void)
{};
int init_cursor(cursor_t *cursor)
{
struct radeon_device *rdev;
uint32_t *bits;
uint32_t *src;
int i,j;
int r;
rdev = (struct radeon_device *)os_display->ddev->dev_private;
r = radeon_bo_create(rdev, CURSOR_WIDTH*CURSOR_HEIGHT*4,
4096, false, RADEON_GEM_DOMAIN_VRAM, 0, NULL, NULL, &cursor->robj);
if (unlikely(r != 0))
return r;
r = radeon_bo_reserve(cursor->robj, false);
if (unlikely(r != 0))
return r;
r = radeon_bo_pin(cursor->robj, RADEON_GEM_DOMAIN_VRAM, NULL);
if (unlikely(r != 0))
return r;
r = radeon_bo_kmap(cursor->robj, (void**)&bits);
if (r) {
DRM_ERROR("radeon: failed to map cursor (%d).\n", r);
return r;
};
src = cursor->data;
for(i = 0; i < 32; i++)
{
for(j = 0; j < 32; j++)
*bits++ = *src++;
for(j = 32; j < CURSOR_WIDTH; j++)
*bits++ = 0;
}
for(i = 0; i < CURSOR_WIDTH*(CURSOR_HEIGHT-32); i++)
*bits++ = 0;
radeon_bo_kunmap(cursor->robj);
// cursor->header.destroy = destroy_cursor;
return 0;
};
void __attribute__((regparm(1))) destroy_cursor(cursor_t *cursor)
{
list_del(&cursor->list);
radeon_bo_unpin(cursor->robj);
KernelFree(cursor->data);
__DestroyObject(cursor);
};
static void radeon_show_cursor()
{
struct radeon_device *rdev = (struct radeon_device *)os_display->ddev->dev_private;
if (ASIC_IS_DCE4(rdev)) {
WREG32(RADEON_MM_INDEX, EVERGREEN_CUR_CONTROL);
WREG32(RADEON_MM_DATA, EVERGREEN_CURSOR_EN |
EVERGREEN_CURSOR_MODE(EVERGREEN_CURSOR_24_8_PRE_MULT));
} else if (ASIC_IS_AVIVO(rdev)) {
WREG32(RADEON_MM_INDEX, AVIVO_D1CUR_CONTROL);
WREG32(RADEON_MM_DATA, AVIVO_D1CURSOR_EN |
(AVIVO_D1CURSOR_MODE_24BPP << AVIVO_D1CURSOR_MODE_SHIFT));
} else {
WREG32(RADEON_MM_INDEX, RADEON_CRTC_GEN_CNTL);
WREG32_P(RADEON_MM_DATA, (RADEON_CRTC_CUR_EN |
(RADEON_CRTC_CUR_MODE_24BPP << RADEON_CRTC_CUR_MODE_SHIFT)),
~(RADEON_CRTC_CUR_EN | RADEON_CRTC_CUR_MODE_MASK));
}
}
cursor_t* __stdcall select_cursor(cursor_t *cursor)
{
struct radeon_device *rdev;
cursor_t *old;
uint32_t gpu_addr;
rdev = (struct radeon_device *)os_display->ddev->dev_private;
old = os_display->cursor;
os_display->cursor = cursor;
gpu_addr = radeon_bo_gpu_offset(cursor->robj);
if (ASIC_IS_DCE4(rdev))
{
WREG32(EVERGREEN_CUR_SURFACE_ADDRESS_HIGH, 0);
WREG32(EVERGREEN_CUR_SURFACE_ADDRESS, gpu_addr);
}
else if (ASIC_IS_AVIVO(rdev))
{
if (rdev->family >= CHIP_RV770)
WREG32(R700_D1CUR_SURFACE_ADDRESS_HIGH, 0);
WREG32(AVIVO_D1CUR_SURFACE_ADDRESS, gpu_addr);
}
else {
WREG32(RADEON_CUR_OFFSET, gpu_addr - rdev->mc.vram_start);
}
return old;
};
static void radeon_lock_cursor(bool lock)
{
struct radeon_device *rdev;
rdev = (struct radeon_device *)os_display->ddev->dev_private;
uint32_t cur_lock;
if (ASIC_IS_DCE4(rdev)) {
cur_lock = RREG32(EVERGREEN_CUR_UPDATE);
if (lock)
cur_lock |= EVERGREEN_CURSOR_UPDATE_LOCK;
else
cur_lock &= ~EVERGREEN_CURSOR_UPDATE_LOCK;
WREG32(EVERGREEN_CUR_UPDATE, cur_lock);
} else if (ASIC_IS_AVIVO(rdev)) {
cur_lock = RREG32(AVIVO_D1CUR_UPDATE);
if (lock)
cur_lock |= AVIVO_D1CURSOR_UPDATE_LOCK;
else
cur_lock &= ~AVIVO_D1CURSOR_UPDATE_LOCK;
WREG32(AVIVO_D1CUR_UPDATE, cur_lock);
} else {
cur_lock = RREG32(RADEON_CUR_OFFSET);
if (lock)
cur_lock |= RADEON_CUR_LOCK;
else
cur_lock &= ~RADEON_CUR_LOCK;
WREG32(RADEON_CUR_OFFSET, cur_lock);
}
}
void __stdcall move_cursor(cursor_t *cursor, int x, int y)
{
struct radeon_device *rdev;
rdev = (struct radeon_device *)os_display->ddev->dev_private;
int hot_x = cursor->hot_x;
int hot_y = cursor->hot_y;
int w = 32;
radeon_lock_cursor(true);
if (ASIC_IS_DCE4(rdev)) {
WREG32(EVERGREEN_CUR_POSITION,(x << 16) | y);
WREG32(EVERGREEN_CUR_HOT_SPOT, (hot_x << 16) | hot_y);
WREG32(EVERGREEN_CUR_SIZE, ((w - 1) << 16) | 31);
} else if (ASIC_IS_AVIVO(rdev)) {
WREG32(AVIVO_D1CUR_POSITION, (x << 16) | y);
WREG32(AVIVO_D1CUR_HOT_SPOT, (hot_x << 16) | hot_y);
WREG32(AVIVO_D1CUR_SIZE, ((w - 1) << 16) | 31);
} else {
uint32_t gpu_addr;
int xorg =0, yorg=0;
x = x - hot_x;
y = y - hot_y;
if( x < 0 )
{
xorg = -x + 1;
x = 0;
}
if( y < 0 )
{
yorg = -hot_y + 1;
y = 0;
};
WREG32(RADEON_CUR_HORZ_VERT_OFF,
(RADEON_CUR_LOCK | (xorg << 16) | yorg ));
WREG32(RADEON_CUR_HORZ_VERT_POSN,
(RADEON_CUR_LOCK | (x << 16) | y));
gpu_addr = radeon_bo_gpu_offset(cursor->robj);
/* offset is from DISP(2)_BASE_ADDRESS */
WREG32(RADEON_CUR_OFFSET,
(gpu_addr - rdev->mc.vram_start + (yorg * 256)));
}
radeon_lock_cursor(false);
}
void __stdcall restore_cursor(int x, int y)
{
};
bool init_display(struct radeon_device *rdev, videomode_t *usermode)
{
struct drm_device *dev;
cursor_t *cursor;
bool retval = true;
u32 ifl;
ENTER();
os_display = GetDisplay();
dev = os_display->ddev = rdev->ddev;
ifl = safe_cli();
{
list_for_each_entry(cursor, &os_display->cursors, list)
{
init_cursor(cursor);
};
os_display->restore_cursor(0,0);
os_display->init_cursor = init_cursor;
os_display->select_cursor = select_cursor;
os_display->show_cursor = NULL;
os_display->move_cursor = move_cursor;
os_display->restore_cursor = restore_cursor;
os_display->disable_mouse = disable_mouse;
select_cursor(os_display->cursor);
radeon_show_cursor();
};
safe_sti(ifl);
// init_bitmaps();
LEAVE();
return retval;
};
struct fb_info *framebuffer_alloc(size_t size, struct device *dev)
{
#define BYTES_PER_LONG (BITS_PER_LONG/8)
#define PADDING (BYTES_PER_LONG - (sizeof(struct fb_info) % BYTES_PER_LONG))
int fb_info_size = sizeof(struct fb_info);
struct fb_info *info;
char *p;
if (size)
fb_info_size += PADDING;
p = kzalloc(fb_info_size + size, GFP_KERNEL);
if (!p)
return NULL;
info = (struct fb_info *) p;
if (size)
info->par = p + fb_info_size;
return info;
#undef PADDING
#undef BYTES_PER_LONG
}
void framebuffer_release(struct fb_info *info)
{
kfree(info);
}
/* 23 bits of float fractional data */
#define I2F_FRAC_BITS 23
#define I2F_MASK ((1 << I2F_FRAC_BITS) - 1)
/*
* Converts unsigned integer into 32-bit IEEE floating point representation.
* Will be exact from 0 to 2^24. Above that, we round towards zero
* as the fractional bits will not fit in a float. (It would be better to
* round towards even as the fpu does, but that is slower.)
*/
__pure uint32_t int2float(uint32_t x)
{
uint32_t msb, exponent, fraction;
/* Zero is special */
if (!x) return 0;
/* Get location of the most significant bit */
msb = __fls(x);
/*
* Use a rotate instead of a shift because that works both leftwards
* and rightwards due to the mod(32) behaviour. This means we don't
* need to check to see if we are above 2^24 or not.
*/
fraction = ror32(x, (msb - I2F_FRAC_BITS) & 0x1f) & I2F_MASK;
exponent = (127 + msb) << I2F_FRAC_BITS;
return fraction + exponent;
}