Complex floating-point sequential logic in Verilog

I'm trying to write a synthesizable 3D rasterizer in Verilog/SystemVerilog. The rasterizer right now is not really a 3D rasterizer: it just receives six 32-bits floats for vertex position (vertA_pos_x, vertA_pos_y, vertB_pos_x, vertB_pos_y, vertC_pos_x, vertC_pos_y) and nine 8-bits integers for vertex coloring (vertA_color_r, vertA_color_g, vertA_color_b, vertB_color_r, vertB_color_g, vertB_color_b, vertC_color_r, vertC_color_g, vertC_color_b).

Positions' ranges are 0.0f ~ 1.0f, 0.0f representing the top/left side of the screen, 0.5f the middle of it and 1.0f the bottom/right side.

The raster work would be to, first, count how many raster lines are required. Given that the framebuffer height is 240 pixels, vertex A is the top vertex, B is the bottom-left one, C is the bottom-right one and X is the bottommost vertex (either B or C; this has to be calculated), the number of raster lines is given by `(vertX_pos_y - vertA_pos_y) / 240`.

This part of the rasterization process is complex enough to expose my doubts, so I'll stop explaining how I would proceed here.

Now what I want to know is how to implement such "complex" logic in Verilog (it is "complex" because it is sequential and takes more than one clock cycle, which is not exactly the most pleasant kind of thing to design with a hardware description language).

I am using Altera's Quartus and so I'm mainly interested in Altera solutions.

The floating-point operation megafunctions that come with Quartus all require more than one clock cycle to finish, so, to implement "simple" calculations like `(vertX_pos_y - vertA_pos_y) / 240`, I'm assuming a fairly boring-to-write and error-prone state machine is necessary. My biggest expectation is that someone will tell me I don't need that, but if that's not the case, I still would like to know how people generally design things like these.

Also notice that I'm very new to Verilog and hardware design in general, so I'm sorry if I say something stupid. Ideas?

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To give an example, say you wanted to do `(a*b) + c`, where `x*y` takes 3 clock cycles and `x+y` takes 1 clock cycle. Pipelining simply means inserting banks of registers to line up the delays. In the example, the input `c` is delayed to match up with the latency of the multiply. So overall, the operation will have a latency of 3 + 1 = 4 clock cycles.