| NOTES about msm drm/kms driver: |
| |
| In the current snapdragon SoC's, we have (at least) 3 different |
| display controller blocks at play: |
| + MDP3 - ?? seems to be what is on geeksphone peak device |
| + MDP4 - S3 (APQ8060, touchpad), S4-pro (APQ8064, nexus4 & ifc6410) |
| + MDP5 - snapdragon 800 |
| |
| (I don't have a completely clear picture on which display controller |
| maps to which part #) |
| |
| Plus a handful of blocks around them for HDMI/DSI/etc output. |
| |
| And on gpu side of things: |
| + zero, one, or two 2d cores (z180) |
| + and either a2xx or a3xx 3d core. |
| |
| But, HDMI/DSI/etc blocks seem like they can be shared across multiple |
| display controller blocks. And I for sure don't want to have to deal |
| with N different kms devices from xf86-video-freedreno. Plus, it |
| seems like we can do some clever tricks like use GPU to trigger |
| pageflip after rendering completes (ie. have the kms/crtc code build |
| up gpu cmdstream to update scanout and write FLUSH register after). |
| |
| So, the approach is one drm driver, with some modularity. Different |
| 'struct msm_kms' implementations, depending on display controller. |
| And one or more 'struct msm_gpu' for the various different gpu sub- |
| modules. |
| |
| (Second part is not implemented yet. So far this is just basic KMS |
| driver, and not exposing any custom ioctls to userspace for now.) |
| |
| The kms module provides the plane, crtc, and encoder objects, and |
| loads whatever connectors are appropriate. |
| |
| For MDP4, the mapping is: |
| |
| plane -> PIPE{RGBn,VGn} \ |
| crtc -> OVLP{n} + DMA{P,S,E} (??) |-> MDP "device" |
| encoder -> DTV/LCDC/DSI (within MDP4) / |
| connector -> HDMI/DSI/etc --> other device(s) |
| |
| Since the irq's that drm core mostly cares about are vblank/framedone, |
| we'll let msm_mdp4_kms provide the irq install/uninstall/etc functions |
| and treat the MDP4 block's irq as "the" irq. Even though the connectors |
| may have their own irqs which they install themselves. For this reason |
| the display controller is the "master" device. |
| |
| For MDP5, the mapping is: |
| |
| plane -> PIPE{RGBn,VIGn} \ |
| crtc -> LM (layer mixer) |-> MDP "device" |
| encoder -> INTF / |
| connector -> HDMI/DSI/eDP/etc --> other device(s) |
| |
| Unlike MDP4, it appears we can get by with a single encoder, rather |
| than needing a different implementation for DTV, DSI, etc. (Ie. the |
| register interface is same, just different bases.) |
| |
| Also unlike MDP4, with MDP5 all the IRQs for other blocks (HDMI, DSI, |
| etc) are routed through MDP. |
| |
| And finally, MDP5 has this "Shared Memory Pool" (called "SMP"), from |
| which blocks need to be allocated to the active pipes based on fetch |
| stride. |
| |
| Each connector probably ends up being a separate device, just for the |
| logistics of finding/mapping io region, irq, etc. Idealy we would |
| have a better way than just stashing the platform device in a global |
| (ie. like DT super-node.. but I don't have any snapdragon hw yet that |
| is using DT). |
| |
| Note that so far I've not been able to get any docs on the hw, and it |
| seems that access to such docs would prevent me from working on the |
| freedreno gallium driver. So there may be some mistakes in register |
| names (I had to invent a few, since no sufficient hint was given in |
| the downstream android fbdev driver), bitfield sizes, etc. My current |
| state of understanding the registers is given in the envytools rnndb |
| files at: |
| |
| https://github.com/freedreno/envytools/tree/master/rnndb |
| (the mdp4/hdmi/dsi directories) |
| |
| These files are used both for a parser tool (in the same tree) to |
| parse logged register reads/writes (both from downstream android fbdev |
| driver, and this driver with register logging enabled), as well as to |
| generate the register level headers. |
